(Received for publication, September 27, 1996)
From the University of Colorado Health Sciences Center, Department of Pathology, Denver, Colorado 80262
We have demonstrated that a 120-kDa protein, identified as Cbl, becomes rapidly phosphorylated on tyrosine residues following stimulation of factor-dependent cells with interleukin-3 (IL-3). Little or no phosphorylation of Cbl was observed in the absence of IL-3 stimulation and phosphorylation is maximal by 20-30 min after IL-3 stimulation. Association of Cbl with Grb2 was noted in unstimulated cells, and the amount of Cbl associated with Grb2 increased following IL-3 stimulation. The p85 subunit of phosphatidylinositol 3-kinase was constitutively associated with Cbl. Approximately 10% of the PI kinase activity present in anti-phosphotyrosine immunoprecipitates was present in anti-Cbl immunoprecipitates of IL-3-stimulated cells. The constitutive association of Cbl with Fyn was also observed. Cbl was observed to bind to bacterial fusion proteins encoding the unique, SH3, and SH2 domains of Fyn, Hck, and Lyn. The SH2 domain of Fyn alone was able to bind Cbl to nearly the same extent as did the fusion protein encoding the unique, SH3, and SH2 domains. This was not the case for the SH2 domain of Hck, however, as binding of the Hck fusion protein to Cbl appeared to require multiple domains. The binding of the fusion proteins to Cbl occurred regardless of whether Cbl was tyrosine-phosphorylated or not, and the binding could not be disrupted by the addition of 30 mM free phosphotyrosine. These data suggest the unexpected conclusion that the Fyn SH2 domain may bind to Cbl in a phosphotyrosine-independent manner.
Stimulation of type I cytokine family receptors with their ligands
results in the rapid tyrosine phosphorylation of multiple cellular
proteins including the receptors themselves. Since these receptors do
not encode intrinsic protein-tyrosine kinase activity (1, 2, 3, 4, 5, 6, 7, 8), the
activation of nonreceptor tyrosine kinases, such as the Janus and Src
families of tyrosine kinases, is critical in signaling events.
Investigations utilizing cell lines lacking specific Janus family
members has indicated that they are critical in signal transduction
response to cytokines (9, 10). Similar studies have not been conducted to date with Src-like kinases. In addition to understanding which tyrosine kinases are activated, the identification of downstream signaling molecules is fundamental to understanding signal
transduction. We have been investigating the activation of Src-like
kinases in signal transduction by the IL-31
receptor. Following IL-3 stimulation of the murine myeloid cell line
32D cl3, we have observed the activation of three Src-like kinases:
Fyn, Hck, and Lyn (11). As part of a study to examine the interaction
of Src-like kinases with the subunit of the IL-3 receptor, we
observed that a tyrosine-phosphorylated protein of 120 kDa bound to
bacterial fusion proteins containing the unique, SH3, and SH2 domains
of Fyn, Hck, and Lyn.2 The current study
was initiated to determine whether this protein was Cbl.
The Cbl protein represents the cellular homologue of the oncogene present in the Cas-NS-1 retrovirus (12). Sequence analysis of the Cbl cDNA revealed that the protein contains 913 amino acids, a putative nuclear localization sequence in its N-terminal region, a "RING finger" motif typical of numerous DNA-binding proteins, and several proline-rich sequences in its C-terminal half that may serve as SH3 domain binding sites (12). In spite of the presence of a nuclear localization signal and a DNA-binding motif, there is no evidence that Cbl is present in the nucleus or that it binds to DNA (12, 13). Recent studies have demonstrated that Cbl becomes tyrosine-phosphorylated following stimulation of the following receptors: the T-cell receptor (14, 15, 16), the B-cell receptor (17, 18), the Fc receptor (19, 20), the epidermal growth factor receptor (21, 22, 23, 24), the erythropoietin receptor (25), and the receptor for granulocyte-macrophage colony-stimulating factor (25). The Cbl protein is also phosphorylated in cells expressing either v-Abl or BCR-ABL (26, 27). In receptor-stimulated cells, Cbl has been observed to associate with a variety of proteins by either co-immunoprecipitation studies or binding to bacterial fusion proteins. Association has been observed with PI 3-kinase in a phosphotyrosine-dependent manner via SH2 and SH3 domains (14, 15, 21, 24, 27), with the SH3 domain of Lyn (19, 20), with the SH2 and SH3 domains of Fyn (15, 19), with the SH2 domains of Crk (27), and with Grb2 via one of its SH3 domains (16, 18, 24, 25). The association of Cbl with the p85 subunit of PI 3-kinase and Grb2 suggests that phosphorylation of Cbl may regulate activation of PI 3-kinase and Ras. It is not clear whether Cbl can associate with all of these molecules in the same cell, or in different cell types. In this report, we demonstrate that Cbl is the 120-kDa phosphoprotein observed in IL-3-stimulated cells. Cbl was observed to associate with Grb2, Fyn, and PI 3-kinase. The association of Cbl with Grb2 following cytokine stimulation is consistent with a previous report (25); however, the described interaction Cbl with Fyn and PI 3-kinase following cytokine stimulation is novel to this report. The association of Cbl with Fyn may be mediated by the SH2 domain of Fyn binding to Cbl in a phosphotyrosine-independent manner.
The 32D cl3 cell line was obtained from Dr. Joel Greenberger (University of Pittsburgh, Pittsburgh, PA) and was maintained as described (28). Recombinant murine IL-3 was obtained from Collaborative Biomedical Products (Bedford, MA).
Immunoprecipitation and ImmunoblottingImmunoprecipitation
was performed as described previously (11). Cells were lysed either
with RIPA (150 mM NaCl, 50 mM Tris (pH 7.4), 2 mM EGTA, 1% Triton X-100, 0.25% sodium deoxycholate, 1 mM sodium orthovanadate) or with EB (50 mM
NaCl, 10 mM Tris (pH 7.4), 5 mM EDTA, 50 mM NaF, 1% Triton X-100, 1 mM sodium
orthovanadate). Both lysis buffers were supplemented with 100 units/ml
aprotinin (Calbiochem, La Jolla, CA). Rabbit anti-Lyn, rabbit anti-p85
subunit of PI 3-kinase, rabbit anti-Grb2, rabbit anti-Fyn coupled to
agarose beads, and anti-phosphotyrosine monoclonal antibody 4G10
coupled to agarose beads were obtained from Upstate Biotechnology, Inc. (Lake Placid, NY). Antibodies to Cbl and Hck were obtained from Santa
Cruz Biotechnology (Santa Cruz, CA). Additional antibodies to PI
3-kinase, Lyn, and Grb2 were obtained from Transduction Laboratories
(Lexington, KY). A polyclonal antibody to a GST fusion protein
containing a region of the subunit of the murine IL-3 receptor was
raised in rabbits and affinity-purified. Immunoprecipitated proteins
were resolved on SDS-polyacrylamide gels and electrotransferred to
Immobilon membrane (Millipore, Bedford, MA). Immunoblotting was
conducted as described using the Enhanced Chemiluminescence Lighting
(ECL) system according to manufacturer's recommendations (Amersham
Corp.). All gels were 7% polyacrylamide gels except those used in the
analysis of Grb2, which were 12%.
Reactions were a
modification of a previously described protocol (29, 30). The
immunoprecipitated proteins were washed three times with RIPA, twice
with PAN (20 mM PIPES (pH 7.0), 20 µl/ml aprotinin, 100 mM NaCl), and resuspended in 50 µl of PAN. A 5-µl
aliquot of each sample was removed and placed in a new tube, and 1 µl
of 2 mg/ml phosphatidylinositol in 4.5 mM EGTA, 10%
Me2SO was added to each reaction. The tubes were incubated at room temperature for 10 m before addition of the reaction
mixture containing ATP and incubation at 30 °C for 15 m. The
final reaction mixture contained 20 mM HEPES (pH 7.4), 5 mM MgCl2, 0.45 mM EGTA, 10 µM ATP (5 µCi of [-32P]ATP), and 0.2 mg/ml PI. Reactions were terminated by the addition of 0.1 ml of 1 M HCl, and extracted with 0.2 ml of
CHCl3:methanol (1:1). After discarding the aqueous phase,
the organic phase was re-extracted with 1 M HCl:methanol
(1:1), and dried in a Savant SpeedVac. The samples were dissolved in 10 µl of CHCl3:methanol, spotted on Silica Gel 60 plates (E. Merck) that had been impregnated with sodium tartrate. Plates were
developed in CHCl3:methanol:4 M
NH4OH (9:7:2). After chromatography, the plate was allowed
to dry prior to autoradiography.
Bacterial expression vectors encoding different regions of Fyn, Hck, or Lyn coupled to GST were either constructed for this study or were provided by other investigators. The following expression vectors were obtained from Dr. John Cambier (National Jewish Center for Immunology and Respiratory Diseases, Denver, CO): GST-FYN-(1-255), GST-FYN-SH2, GST-FYN-SH3, and GST-FYN-(1-27) (31). GST-HCK-(1-61), referred to as GST-HCK-unique, was obtained from Dr. Clifford Lowell (University of California, San Francisco, CA) (32).
The following GST fusion proteins were prepared for this study:
GST-FYN, GST-HCK, GST-LYN, GST-HCK-SH3, and GST-HCK-SH2. The unique,
SH3, and SH2 domains of Fyn, Hck, and Lyn were amplified by PCR and
cloned into GEX-3X. The primers and the insertion sites for each
constructions are as follows. FYN was inserted between the
BamHI and EcoRI sites (sense primer,
5-GAAGATCTGGCCTGTGTGCAATGTAAG-3
; antisense primer,
5
-GAGAATTCGGCCACAAAGAGTGTCAC-3
); HCK was inserted between the
BamHI and EcoRI sites (sense primer,
5
-GAAGATCTAAGTCCAAGTTCCTCCAG-3
; antisense primer,
5
-GAGAATTCCCCGTCGTTCCCCTTCTT-3
); and LYN was inserted between the
BamHI and EcoRI sites (sense primer,
5
-GAAGATCTGGATGTATTAAATCAAAA-3
; antisense primer,
5
-GAGAATTCGGCCACCACAATGTCACC-3
). The SH3 domain of Hck was amplified
by PCR (sense primer, 5
-CAGATCTATTACCAGGCCATTCACCA-3
; antisense
primer, 5
-GAATCCAGAGAGTCAACGCGGGCGAC-3
), ligated to the pCR2
cloning vector (InVitrogen) and plasmid DNA purified. The vector was
then cut with BglII and EcoRI and ligated into pGEX-3X at the BamHI and EcoRI sites to generate
GST-HCK-SH3. The SH2 domain of Hck was amplified by PCR (sense primer,
5
-GTTAGATCTATGGAGACAGAGGAGTGGTT-3
; antisense primer,
5
-GAGAATTCCCCGTCGTTCCCCTTCTT-3
), ligated into pCR2, and plasmid DNA
purified. The SH2 domain was released by digestion with
BglII and EcoRI and ligated into the
BamHI sites and EcoRI sites of pGEX-4T3 to
generate GST-HCK-SH2.
The GEX expression vectors were introduced into competent DH5
bacteria, and expression of GST fusion proteins was induced as follows.
Colonies picked from plates were grown in 50 ml of Luria Broth
overnight. The cultures were diluted 1:20 and grown for 2 h, after
which isopropyl-1-thio-
-D-galactopyranoside was added at
a final concentration of 0.1 mM. The cultures were then grown for an additional 4 h before protein purification. Bacteria were pelleted at 6000 rpm for 10 m in a Beckman JA10 rotor. The pelleted cells were resuspended in 20 ml of Lysis Buffer (50 mM Tris (pH 8.0), 2 mM EDTA) containing 200 units/ml aprotinin, and lysed by sonication. To aid in protein
solubilization, Triton X-100 was added to a final concentration of 1%,
and incubated for 30 m at 4 °C. Cellular debris was removed by
centrifugation at 9,500 rpm for 10 m. Supernatants were incubated
with 2 ml of a 50% slurry of glutathione-agarose beads
(Sigma) for 1 h at 4 °C. The beads were
isolated by centrifugation and washed with lysis buffer three times.
The fusion protein was removed from the beads by the addition of
reduced glutathione. Excess glutathione was removed from the isolated
fusion protein by centrifugation using Centrex UF-2 10K Spin Columns
(Schleicher & Schuell).
Binding assays were conducted by adding 2 nmol of the desired GST fusion protein to cell lysate prepared as described above in a final volume of 1 ml. Following a 1-h incubation at 4 °C on a rocking platform, 40 µl of glutathione-agarose (Sigma) was added and incubated for 1 h. The bound proteins were washed three times with RIPA, resolved on SDS-polyacrylamide gels, and subjected to immunoblotting as described above.
We have previously described the activation of three
Src-like tyrosine kinases following stimulation of 32D cl3 cells with IL-3 (11). As part of a study to examine the interaction of Fyn, Hck,
and Lyn with the subunit of the IL-3 receptor, we observed that GST
fusion proteins encoding the unique, SH3, and SH2 domains of these
three kinases appeared to bind to a tyrosine-phosphorylated protein of
approximately 120 kDa.2 Based upon several recently
published studies, we investigated whether this protein might be Cbl
since its molecular mass is 120 kDa (14, 15, 16, 19, 20, 22, 25). To
determine whether this was the case, anti-Cbl immunoprecipitates were
immunoblotted with the anti-phosphotyrosine antibody 4G10. The results
of this study (Fig. 1), indicate that Cbl is
phosphorylated following stimulation of 32D cl3 cells with IL-3. A
major band of approximately 120 kDa is observed in the anti-Cbl
immunoprecipitate immunoblotted with anti-phosphotyrosine antibody. A
minor band of 120 kDa can be seen in the anti-phosphotyrosine
immunoprecipitate that co-migrates with the tyrosine-phosphorylated
band observed in the anti-Cbl immunoprecipitate (Fig. 1, compare
lanes 2 and 4). The tyrosine-phosphorylated band
of 120 kDa also co-migrates with the 120-kDa band observed in a
parallel blot probed with the anti-Cbl antibody (Fig. 1, lanes
7 and 8). The anti-Cbl immunoblot also indicates that
only a small portion of the Cbl protein is observed in an anti-Cbl immunoprecipitate (Fig. 1, compare lane 6 with lanes
7 or 8). A comparison of the relative densities of the
band in lanes 6-8 indicates that only 12% of the Cbl
protein present in anti-Cbl immunoprecipitates is present in the
anti-phosphotyrosine immunoprecipitate.
The time course of Cbl phosphorylation was also examined. The results
in Fig. 2 suggest that phosphorylation of Cbl can be detected as early as 2 m after IL-3 stimulation and is maximal 20-30 min after stimulation (Fig. 2). This time course was
consistently observed in three independent studies. Examination of
longer time periods revealed that tyrosine phosphorylation of Cbl could
be detected for up to 4 h post-stimulation (data not shown).
Immunoblotting of lanes 7-12 with anti-Cbl antiserum
indicated that the amount of Cbl protein did not change over the time
period examined (data not shown).
Association of Cbl with Grb2
Several previous investigations
have noted the association of Cbl with the Grb2 protein (16, 24, 25).
This possibility was examined by immunoprecipitating unstimulated and
IL-3-stimulated cell lysates with either anti-Cbl or anti-Grb2 antisera
and immunoblot analysis. Immunoblotting the anti-Grb2
immunoprecipitates with anti-Grb2 antisera revealed the expected band
of 23 kDa (Fig. 3). The amount of Grb2 present in all
lysates did not appear to change following IL-3 stimulation (Fig. 3).
Anti-Cbl immunoprecipitates of unstimulated cells contained low amounts
Grb2 (Fig. 3). IL-3-stimulation resulted in a 22-fold increase in the
amount of Grb2 associated with Cbl (Fig. 3, lane 1 versus lane
2). Densitometry indicates that 27% of Grb2 observed in anti-Grb2
immunoprecipitates was present in the anti-Cbl immunoprecipitates of
IL-3-stimulated cells. These results clearly demonstrate the
association of a fraction of the total cellular Grb2 with Cbl in
unstimulated cells and an increase in that association following IL-3
stimulation.
Association of Cbl with Phosphatidylinositol 3-Kinase
Other
investigators have reported the association of Cbl with the p85 subunit
of PI 3-kinase (14, 15, 21, 24, 27). This was investigated by
immunoprecipitation of unstimulated and IL-3-stimulated cell lysates
with anti-phosphotyrosine, anti-Cbl, and anti-PI 3-kinase antibodies,
and by immunoblotting with these same antibodies. IL-3 stimulation
resulted in the phosphorylation of numerous proteins on tyrosine
residues including the subunit and Cbl; however, tyrosine
phosphorylation of the p85 subunit of PI 3-kinase was not observed
(Fig. 4, lane 6, top panel). The position of the p85 subunit was determined by reprobing the same blot
with anti-p85 antibody. Immunoprecipitation of Cbl was observed with
anti-phosphotyrosine antibody in lysates of IL-3-stimulated cells and
with anti-Cbl antibody in both unstimulated and stimulated cell lysates
(Fig. 4, lanes 1-4, middle panel); however, no
Cbl protein was detected in immunoblots of the anti-p85
immunoprecipitates of either unstimulated or stimulated cell lysates
(Fig. 4, lanes 5 and 6, middle panel).
Consistent with results shown in Fig. 1, Cbl was detected in an
anti-phosphotyrosine immunoprecipitates of IL-3-stimulated cells (Fig.
4, lane 2, middle panel). The p85 subunit of PI
3-kinase was detected by anti-p85 immunoblotting of 4G10
immunoprecipitates from IL-3-stimulated cells and in anti-p85 immunoprecipitates of unstimulated and stimulated cell lysates. The
presence of the p85 subunit of PI 3-kinase was detected by immunoblotting with an anti-p85 subunit antibody. Larger amounts of p85
were detected in the anti-p85 immunoprecipitates. There was a clear
increase in the amount of p85 detected in anti-phosphotyrosine immunoprecipitates of IL-3-stimulated cells, relative to unstimulated cells. There was a low but detectable amount of p85 in the anti-Cbl immunoprecipitates; however, the amount of p85 in anti-Cbl
immunoprecipitates did not increase following IL-3 stimulation (Fig. 4,
lanes 5 and 6, bottom panel). The
anti-PI 3-kinase antibody did co-precipitate tyrosine-phosphorylated
proteins with molecular masses of 145, 75, 56, 48, and a broad band at
approximately 95-100 kDa from IL-3-stimulated cells (Fig. 4,
lane 8, top panel). The 56-kDa band was also
observed in the anti-phosphotyrosine immunoprecipitate of
IL-3-stimulated cells and most likely represents Shc (data not shown).
The identity of 145-kDa band is not the
subunit since it does not
react with anti-
antibodies; however, it may represent the recently
described SHIP protein, which has been shown to associate with Shc
(33, 34, 35).
To provide additional evidence that PI 3-kinase associates with Cbl,
anti-Cbl immunoprecipitates were assayed for PI 3-kinase activity in
comparison to anti-p85 and anti-phosphotyrosine immunoprecipitates. PI
3-kinase activity was present in the anti-phosphotyrosine
immunoprecipitates of IL-3-stimulated cells (Fig. 5,
lanes 1-4). The amount of kinase activity in
anti-phosphotyrosine immunoprecipitates increased with the length of
stimulation and appeared to plateau after 10-20 min (Fig. 5 and data
not shown). PI 3-kinase activity was also present in anti-p85
immunoprecipitates at all time points examined (Fig. 5, lanes
9-12). PI kinase activity was detectable in anti-Cbl immunoprecipitates (Fig. 5, lanes 7 and 8). The
PI kinase activity present in anti-Cbl immunoprecipitates appears to
peak at 5 min and declines by 20 min after IL-3 stimulation. It is
clear from the data in Fig. 5 that the amount of PI kinase activity
present in anti-Cbl immunoprecipitates is dramatically less than that present in either the anti-phosphotyrosine or anti-p85
immunoprecipitates. PhosphorImager analysis quantitation of the spots
corresponding to PIP in Fig. 5 reveals that at the peak time
point, the amount of kinase activity in anti-Cbl immunoprecipitates
corresponded to 10% of the amount observed in anti-p85
immunoprecipitates or 10% of the amount activity observed at 20 min in
anti-phosphotyrosine immunoprecipitates.
Association of Cbl with the Fyn Tyrosine Kinase
We have
previously described the activation of multiple Src-like kinases (Fyn,
Hck, and Lyn), following stimulation of 32D cl3 cells with IL-3 (11).
The association of Cbl with Src-like kinases has been described by
other investigators (15, 19, 20). These observations prompted us to
determine whether Cbl was associated with Fyn, Hck, or Lyn in 32D cl3
cells, and whether this association was altered following cytokine
stimulation. Lysates of unstimulated and IL-3-stimulated cells were
immunoprecipitated with anti-Cbl antibody and immunoblotted with
anti-Fyn monoclonal antibody. Cbl was observed to co-precipitate Fyn
from lysates of both unstimulated and IL-3-stimulated cells (Fig.
6). There was no apparent change in the amount of Fyn
associated with Cbl following IL-3 stimulation (Fig. 6). Similar
immunoblotting studies conducted with anti-Hck and anti-Lyn did not
reveal association of these kinases with Cbl (data not shown).
Phosphotyrosine-independent Binding of Cbl to Bacterial Fusion Proteins Encoding the unique, SH3, and SH2 Domains of Src-like Kinases
As mentioned above, the tyrosine phosphorylation of a
120-kDa protein in IL-3-stimulated 32D cl3 cells was first detected in
binding studies utilizing GST fusion proteins containing the unique,
SH3, and SH2 domains of Fyn, Hck, or Lyn. Fig. 7 shows the results of one such study, in which the binding of Cbl from lysates
of IL-3-stimulated 32D cl3 cells to GST-FYN and GST-HCK is examined. No
binding of Cbl was observed using GST (Fig. 7, lanes 1 and
2). GST-FYN bound to Cbl in lysates of either unstimulated and IL-3-stimulated cells (Figs. 7, lanes 3 and
4). There was no difference in the amount of Cbl bound to
GST-FYN when unstimulated or stimulated cell extracts were used in the
binding assays, and no detectable tyrosine-phosphorylated Cbl was
detected in unstimulated cells (Fig. 7, lanes 3 and
4, top and bottom panels). These
results suggested that the binding of Cbl to GST-FYN might be largely phosphotyrosine-independent. GST-HCK was also observed to bind to Cbl
in lysates of both unstimulated and IL-3-stimulated cells (Fig. 7,
lanes 9 and 10). There did appear to be a 2-fold
increase in the amount of Cbl that bound to GST-HCK when lysates of
IL-3-stimulated cells were used, compared to the amount of Cbl bound
when lysates of unstimulated cells were used. Consistent with above
observations using GST-FYN, tyrosine phosphorylation of Cbl was not
observed in lysates of unstimulated cells.
Phosphotyrosine-dependent interactions most likely involve
SH2 domains (36, 37, 38), while phosphotyrosine-independent binding would
be expected to involve either the unique or SH3 domain, or both. To
determine what region(s) of Fyn and Hck were involved in binding to
Cbl, we used different GST fusion proteins containing all or part of a
specific domain of either Fyn or Hck and examined their binding to Cbl
by anti-Cbl immunoblotting or to tyrosine-phosphorylated proteins by
anti-phosphotyrosine immunoblotting. GST-FYN-SH2 bound to Cbl present
in both unstimulated and stimulated cells (Fig. 7,
lanes 7 and 8); however, only the Cbl in
IL-3-stimulated cells was tyrosine-phosphorylated. No binding of Cbl
was observed to the GST-FYN-unique (Fig. 7, lanes 5 and
6) or to GST-FYN-SH3 (data not shown). When GST-FYN-SH2 was
used in the binding assay, there was a 2-fold increase in the amount of
Cbl that bound when lysates of IL-3-stimulated cells were used compared
to the amount that bound when lysates of unstimulated cells were
used.
In contrast to the results obtained with single domains of Fyn, no
binding to Cbl was observed when GST fusion proteins containing either
the unique, the SH3, or the SH2 domains of Hck were used (Fig. 7,
lanes 11-16). This suggests that binding of Hck to Cbl may
involve the interactions of multiple domains to generate a stable
complex. The large band migrating immediately above Cbl in the
anti-phosphotyrosine blot includes the tyrosine-phosphorylated subunit of the IL-3 receptor. Identity of this band was confirmed by
immunoblotting with an anti-
subunit antibody (data not shown).
The data in Fig. 7 clearly suggests that Fyn and Cbl may associate, via the SH2 domain of Fyn, in phosphotyrosine-independent manner. As another means to determine whether this binding was phosphotyrosine-independent, either 30 mM phosphoserine or 30 mM phosphotyrosine was added to binding reactions involving GST-FYN, GST-HCK, or GST-LYN (Fig. 8). In each of these cases, we did not observe a decrease in the amount of Cbl bound to GST-FYN, GST-HCK, or GST-LYN when either phosphoserine or phosphotyrosine was present (Fig. 8). These studies suggest to us that at least a portion of this binding must be mediated by phosphotyrosine-independent interactions.
In this paper we have described the phosphorylation of Cbl on tyrosine following stimulation of factor-dependent 32D cl3 cells with IL-3. Association of Cbl with three other molecules involved in signal transduction was noted; Grb2, Fyn, and the p85 subunit of PI 3-kinase. IL-3 stimulation increased the amount of Grb2 associated with Cbl; however, it did not appear to alter the amount of Fyn or p85 associated with Cbl. Activated PI kinase activity was associated with Cbl following IL-3 stimulation; however, the Cbl-associated activity was only 10% of the activity noted in anti-phosphotyrosine or anti-p85 immunoprecipitates. The association of Cbl with Src-like kinases, the p85 subunit of PI 3-kinase, or PI kinase activity following stimulation of cytokine family receptors has not been described before and is novel to this report. Our results are consistent with a previous publication demonstrating tyrosine phosphorylation of Cbl following stimulation of factor-dependent cells with erythropoietin or GM-CSF (25). In that work, the constitutive association of Grb2 with Cbl, via the SH3 domain of Grb2, was noted.
Using GST fusion proteins in binding assays, we have determined that the SH2 domain of Fyn can bind to Cbl in a phosphotyrosine-independent manner. Observations supporting this conclusion include: (a) GST-FYN-SH2 bound to non-phosphorylated Cbl, and (b) 30 mM phosphotyrosine did not block this binding. While several other investigators have demonstrated that binding of proteins to Cbl is mediated by SH2 domains, none have investigated whether these interactions are phosphotyrosine-dependent. The phosphotyrosine-independent binding of the v-Abl SH2 domain to Shc has been described (39). In addition, a 62-kDa protein has been described that binds the SH2 domain of Lck in a phosphotyrosine-independent manner (40, 41). The possibility that these binding interactions represent the binding of SH2 domains to phospholipid-modified proteins remains to be investigated (42).
Activation of PI 3-kinase by cytokines such as IL-3 and GM-CSF has been
reported by several investigators (43, 44, 45). Although Wang et
al. (43) noted the low level tyrosine-phosphorylation of p85,
other investigators, including this report, have not observed phosphorylation of p85 following stimulation with IL-3 or GM-CSF (45,
46). The fact that PI 3-kinase activity is detected in anti-phosphotyrosine immunoprecipitates (this report and Ref. 45),
suggests that this enzyme is complexed to other tyrosine-phosphorylated proteins. Candidate tyrosine-phosphorylated proteins to which p85/PI
3-kinase might associate include the subunit, Cbl, Src-like kinases, and a protein referred to as p80 (46). Numerous investigators have described the association of PI 3-kinase (and p85) with Cbl following activation of the EGF receptor, the T-cell receptor, and the
B-cell receptor (14, 15, 16, 17, 21, 22, 24, 47). The same association has also
been observed with BCR-ABL (26, 27). Our investigation suggests that
approximately 10% of the PI kinase activity in an anti-phosphotyrosine
immunoprecipitate can be found in an anti-Cbl immunoprecipitate. This
suggests that the majority of PI 3-kinase is associated with other
tyrosine-phosphorylated proteins. To date no investigators have
described the association of p85 directly with the
subunit, and the
subunit does not appear to have the predicted consensus sequence to
which the SH2 domain of p85 might bind.
The association of PI 3-kinase with Src-like kinases is known to occur. Corey et al. (44) demonstrated that activated PI 3-kinase was associated the Lyn and Yes kinases following GM-CSF stimulation. Pleiman et al. (48) have shown that the binding of the SH3 domain of Fyn or Lyn to a proline-rich sequence in p85 results in the activation of PI 3-kinase. The SH3 domain of Fyn was also demonstrated to bind to p85 following activation of the T-cell receptor (49). These results clearly indicate that Src-like kinases may regulate PI 3-kinase activation.
Jücker and Feldman (46) have described the association of a 76-85-kDa tyrosine-phosphorylated protein, referred to as p80, with p85 following IL-3 or GM-CSF stimulation of human TF-1 cells. They have also determined the p80 is highly associated with Src-like kinases (Src, Yes, and Lyn) (46). These investigators, however, did not determine whether active PI 3-kinase is associated with p80. We have observed the co-immunoprecipitation of several tyrosine-phosphorylated proteins with p85, including one that might correspond to p80; however, the major band we have observed has a molecular mass of 95-100 kDa. The identity of p80, as well as other tyrosine-phosphorylated proteins, and their role in regulating PI 3-kinase remain an important question for future studies.
We propose a model in which Cbl functions as an adaptor protein similar to insulin-regulated substrate-1. Unphosphorylated Cbl is associated with molecules such as Grb2 and p85, which could link it to the Ras/Raf/MAP kinase and the PI 3-kinase pathways. Following phosphorylation, Cbl may serve as a binding site to which other signaling molecules bind and become activated. While it may play a role in regulating PI 3-kinase, it is clear that other proteins are also involved. It remains to be determined whether these other proteins, such as Src-like kinases, function independently of Cbl, or whether they are transiently associated with Cbl.
We thank John Cambier and Clifford Lowell for providing some of the GST expression plasmids used in this study. Richard Klinghoffer and Andrius Kazlauskas kindly provided assistance with PI kinase assays. We also acknowledge the services of the University of Colorado Cancer Center DNA Sequencing Core Facility and Antibody Core Facility in support of this research. The PhosphorImager used in this study is part of the Molecular Biology Core of the University of Colorado Cancer Center. The University of Colorado Cancer Center is supported by National Institutes of Health Grant CA46934. We also thank Drs. Mary Reyland and Julie Gelderloos for their comments on the manuscript.