(Received for publication, July 10, 1996, and in revised form, October 25, 1996)
From the Division of Hematology/Oncology, Deaconess
and Beth Israel Hospitals, Department of Medicine, Harvard Medical
School, Boston, Massachusetts 02215, the § Department of
Cell Research and Immunology, Tel Aviv University, Ramat Aviv, 69978 Israel, and the ¶ Department of Protein Chemistry, Genentech,
Inc., South San Francisco, California 94080
Protein-tyrosine kinases, such as HER-2/ErbB-2, have been specifically linked to breast cancer. The Csk-homologous kinase (CHK), formerly MATK, is a tyrosine kinase that contains the Src homology 2 and 3 (SH2 and SH3) domains and demonstrates homology (~50%) to the Csk tyrosine kinase. Like Csk, CHK is able to phosphorylate and inactivate Src family kinases. In this report, we investigated whether CHK is expressed in breast cancer tissues and whether it participates in the ErbB-2 signaling pathway in T47D and MCF-7 breast cancer cell lines. Immunostaining of the CHK protein in breast tissues demonstrated that primary invasive ductal carcinomas, stage II (13 of 15 cases) and stage I (8 of 15 cases), expressed the CHK protein, while this protein was not detected in the adjacent normal tissues from the same patients. To study the role of CHK in the ErbB-2 signaling pathway, glutathione S-transferase fusion proteins containing the SH2 and SH3 domains of CHK were generated. CHK-SH2 and CHK-SH3-SH2, but not CHK-SH3 or CHK-NH2-SH3, precipitated the tyrosine-phosphorylated ErbB-2 upon stimulation with heregulin. EGF or interleukin-6 stimulation of T47D cells failed to induce CHK-SH2 association with ErbB-2, the EGF-receptor, or the interleukin-6 receptor. In vivo association of the tyrosine-phosphorylated ErbB-2 with CHK was observed in co-immunoprecipitation studies with anti-CHK antibodies.
EGF-R, ErbB-3, and ErbB-4 were not detected in the CHK immunoprecipitates or in the precipitates of the GST-SH2 fusion proteins of CHK, suggesting that the association of CHK with ErbB-2 upon heregulin stimulation is receptor-specific (ErbB-2) and ligand-specific (heregulin). These results indicate that CHK might participate in signaling in breast cancer cells by associating, via its SH2 domain, with ErbB-2 following heregulin stimulation.
Protein-tyrosine kinases are involved in the regulation of cell growth and differentiation. The binding of a ligand to the extracellular domain of a cognate receptor protein-tyrosine kinase induces receptor dimerization, stimulation of intrinsic kinase activity, and autophosphorylation. Protein-tyrosine kinases elicit their function by binding and/or phosphorylating intracellular substrate proteins (1-3). The tyrosine-phosphorylated sites in the activated receptors function as high affinity binding sites for proteins containing SH21 domains (1-2, 4-6).
Constitutive activation of these signaling pathways is apparent in many malignancies. A variety of human tumors overexpress the ErbB (HER) family of type I receptor protein-tyrosine kinases (7, 8). Four members of this family are presently known: p170ErbB-1 (epidermal growth factor receptor; EGF-R), p185ErbB-2, p180ErbB-3, and p180ErbB-4 (9-13). In particular, the overexpression of the p185ErbB-2 correlates with a poor clinical prognosis of breast cancer (8-9, 14). The overall amino acid homology within this receptor family ranges from 40 to 50%. All of the family members are characterized by two cysteine-rich regions in the extracellular domain, a single transmembrane region and a large cytoplasmic domain that exhibits tyrosine kinase activity (14).
Several ligands that bind to and stimulate the kinase activity of the
ErbB family members have been identified and are classified as EGF-like
ligands. EGF, HB-EGF, amphiregulin, betacellulin, epiregulin, and
transforming growth factor- (TGF-
) are the ligands for the EGF-R
(ErbB-1) (15-17). Heregulin (HRG) and its rat homologue neu
differentiation factor (NDF) are a subfamily of neuregulins, which are
EGF-like ligands that bind to and activate both ErbB-3 and ErbB-4 (15,
18-24). Recently, betacellulin has been shown to bind ErbB-4 as well
as EGF-R (25). Although none of these factors bind directly to ErbB-2,
both EGF and HRG induce its tyrosine phosphorylation, presumably by
ligand-driven heterodimerization and cross-phosphorylation (15, 24,
26-29). Interestingly, ErbB-2, by heterodimerizing with the EGF-R and
ErbB-3, confers high affinity binding sites for EGF and HRG,
respectively (9, 28).
Upon ligand binding, the activated ErbB receptor family members
interact with different signaling molecules. EGF-R has been shown to
associate with phospholipase C-1, Shc, and Grb-2 (15, 30-32), and
ErbB-2 can associate with phospholipase C-
1, Shc, and
Ras-GTPase-activating protein (15, 33-36). In addition, ErbB-2 can
interact with and activate Src (37, 38), while ErbB-3 associates with
and activates PI 3-kinase (15, 33, 39-42).
We and others have recently identified a cytoplasmic tyrosine kinase, CHK (Csk-homologous kinase), previously referred to as MATK (megakaryocyte-associated tyrosine kinase), and also called Hyl, Ntk, Ctk, Batk, or Lsk (43-52). The CHK protein, abundantly expressed in hematopoietic cells and in human brain (43-45), is composed of 527 amino acids, has an apparent molecular mass of 58 kDa, and shares 50% homology with the human Csk (C-terminal Src kinase) (43, 44). Like Csk, CHK contains SH3, SH2, and tyrosine kinase domains and lacks the Src family N-terminal myristoylation and autophosphorylation sites (43, 53-57).
Here we report that CHK is expressed in human breast cancer but not in adjacent normal breast tissues. Our studies of CHK signaling in breast cancer cell lines MCF-7 and T47D demonstrated in vivo interaction between CHK and activated ErbB-2 upon HRG stimulation. This interaction occurred via the SH2 domain of CHK and was ligand-specific (HRG) and receptor-specific (ErbB-2). This study provides new insights into the regulatory pathways in neoplastic breast tissues.
Recombinant heregulin (rHRG1, 177-244),
rabbit polyclonal anti-ErbB-2 antibodies, and 3E8 monoclonal
anti-ErbB-2 antibodies, were obtained from Genentech, Inc. (San
Francisco, CA) (58). EGF and IL-6 were purchased from Collaborative
Biomedical Products (Bedford, MA) and from R & D Systems (Minneapolis,
MN), respectively. Monoclonal anti-phosphotyrosine antibody (PY20)
conjugated to horseradish peroxidase was obtained from Zymed, Inc. (San
Francisco, CA). Polyclonal antibodies for EGF-R, ErbB-3, ErbB-4, and
polyclonal anti-CHK (anti-LSK) antibodies were obtained from Santa Cruz
Biotechnology (Santa Cruz, CA). Anti-GST monoclonal antibodies were
purchased from Pharmacia Biotech Inc. GST fusion proteins containing
the NH2-SH2 domain of p85 PI 3-kinase and the SH2-SH2-SH3
domains of phospholipase C-
1 were obtained from Santa Cruz
Biotechnology. The primers for the polymerase chain reaction (PCR) were
synthesized by an automated DNA synthesizer (Applied Biosystems model
394). Reagents for electrophoresis were obtained from Bio-Rad. Enhanced chemiluminescence (ECL) reagents were purchased from Amersham Corp. All
other reagents were purchased from Sigma.
Immunohistochemical staining was performed on paraffin-embedded 5-µm-thick tissue sections of human breast cancer. Sections were deparaffinized in xylene and then incubated in decreasing concentrations of ethyl alcohol. After several rinses in water, the slides were incubated in methanol/hydrogen peroxide (1:4) and briefly rinsed in water and then in phosphate-buffered saline (pH 7.6). Subsequent immunohistochemical staining was performed using a 1:100 dilution in phosphate-buffered saline of rabbit anti-CHK antisera (1-h incubation) followed by the addition of the secondary antibodies, peroxidase-conjugated rabbit anti-mouse IgG (Sigma) at 50 µg/ml in phosphate-buffered saline.
Cell LinesThe T47D and MCF-7 human breast cancer cell lines were obtained from ATCC (American Type Culture Collection, Rockville, MD). T47D cells were grown in RPMI 1640 medium (Life Technologies, Inc.) supplemented with 10% fetal bovine serum and 3.5 µg/ml insulin (Sigma).
The MCF-7 cells were grown in minimal essential medium (Life Technologies, Inc.) supplemented with 10% fetal bovine serum, 5 µg/ml insulin (Sigma), 1 mM nonessential amino acids, and 1 mM sodium pyruvate. Prior to stimulation with HRG, EGF, or IL-6, cells were starved overnight in media containing 1% fetal bovine serum and then for 4 h in serum-free medium.
Generation of Flag-CHK Construct in pCDNA3 VectorThe
CHK cDNA (1.6 kilobase pairs) was cloned into EcoRI
sites in the pCDNA3-neo vector. The nucleotide sequence for the
Flag epitope (Asp-Tyr-Lys-Asp-Asp-Asp-Asp-Lys) was introduced to the 5
end of the open reading frame of the CHK cDNA sequence by PCR, using a 1.6-kilobase pair CHK cDNA as a template. The 5
sense primer included a BamHI restriction site, ATG initiation
codon, the Flag sequence, and CHK sequences from nucleotides 269-295 (43). The 3
-antisense primer was composed of CHK sequences from
nucleotides 510-481 (43). The PCR product was double digested with
BamHI and BstEII (New England BioLabs, Beverly,
MA), gel-purified, and then cloned into BamHI and
BstEII sites in the pcDNA3-neo-Flag-CHK. The construct was
analyzed by restriction mapping and nucleotide sequencing.
Transfection of MCF-7 cells was performed using the Lipofectamine (Life Technologies, Inc.) according to the manufacturer's protocol. The transfected cells were selected in 1.2 mg/ml G418 (Sigma). Positive transfectants were chosen based on their immunoreactivity on Western blots probed with polyclonal anti-CHK and monoclonal anti-Flag (M5) antibodies (Eastman Kodak Co.).
Construction and Purification of GST Fusion Proteins of CHKTo express the NH2-SH3 and SH3-SH2 domains of CHK as GST fusion proteins, the corresponding DNA sequences were amplified by PCR with sense and antisense primers of CHK cDNA, which contained BamHI and EcoRI restriction sites. For the NH2-SH3 construct, we used the sense primer from nucleotides 4-27 and the antisense primer from nucleotides 343-321 (43). For the SH3-SH2 construct, we used the sequences from nucleotides 127-150 as the sense primer and from nucleotides 657-634 as the antisense primer (43). The DNA fragments obtained from PCR were restriction-digested with BamHI and EcoRI and ligated into the pGEX-2T vector (Pharmacia). The sequence and orientation were confirmed by sequencing both strands. Construction of the GST fusion proteins of CHK-SH2 and CHK-SH3 was described previously (45).
GST fusion proteins were produced by the induction of transformed
bacteria using 10 mM isopropyl--thiogalactopyranoside
and purified on a large scale by affinity chromatography on
glutathione-Sepharose beads according to the manufacturer's protocol
(Pharmacia).
In order to detect the binding of other proteins to CHK GST fusion proteins, approximately 5 × 106 cells/plate were starved overnight in media containing 1% fetal bovine serum, followed by additional starvation in serum-free medium for 4 h at 37 °C. The starved cells were then stimulated with 10 nM HRG for 8 min or with 100 ng/ml EGF or 100 ng/ml IL-6 for 5 min at room temperature. The stimulation was terminated by the addition of an ice-cold lysis buffer (0.1% SDS, 1% Triton X-100, in Tris-buffered saline containing 10% glycerol, 1 mM EDTA, 0.5 mM Na3VO4, 0.2 mM phenylmethylsulfonyl fluoride, 1 µg/ml aprotinin, and 10 mM leupeptin) (58). Lysates were precleared by centrifugation (14,000 rpm, 15 min) and then incubated for 90 min at 4 °C with 10 µg of GST fusion proteins coupled to glutathione-Sepharose beads. The beads were washed three times with the lysis buffer. For the immunoprecipitation experiments, polyclonal anti-CHK antibody (10 µl), monoclonal anti-ErbB-2 antibody, 3E8 (10 µg/ml), polyclonal anti-ErbB-3 antibody (10 µg/ml), or polyclonal anti-ErbB-4 antibody (10 µg/ml) was used. SDS-sample buffer was added to the samples and analyzed on 7% polyacrylamide SDS-PAGE. Proteins were transferred onto nitrocellulose or Immobilon-PTM (Millipore Corp., Bedford, MA) membranes. Bound proteins were immunoblotted with anti-phosphotyrosine antibody (PY20), polyclonal anti-ErbB-2 antibody, or polyclonal anti-CHK, EGF-R, ErbB-3, or ErbB-4 antibodies. The blots were developed using the ECL system (Amersham). Blots were stripped for 30 min at 55 °C in stripping buffer (100 mM 2-mercaptoethanol, 2% SDS, 62.5 mM Tris-HCl, pH 6.7), according to the manufacturer's protocol (Amersham).
Analyses of CHK
expression in human breast cancer tissues were performed on paraffin
sections derived from 12 breast cancer patients using
immunohistochemistry. CHK protein was found in 13 of 15 invasive ductal
carcinomas, stage II, and in 8 of 15 stage I carcinomas (Fig.
1), while no CHK was detected in the adjacent normal
tissues from the same patients.
CHK Is Associated with Activated ErbB-2 upon Stimulation with HRG
Following our observation that CHK was expressed in human
breast cancer tissues, we have investigated whether CHK might be involved in one of the main signaling pathways in breast cancer mediated by the ErbB family receptors. Experiments were performed using
the T47D breast cancer cell line and the GST fusion protein containing
the SH2 domain of CHK (CHK-SH2). T47D cells express the ErbB family
receptors and the CHK protein as observed by immunohistochemistry (data
not shown). T47D cells were starved overnight in 1% fetal calf serum
in RPMI 1640 and then incubated in serum-free medium for 4 h. The
starved cells were then stimulated with HRG (10 nM) for the
indicated times (Fig. 2). Cells were lysed, and the
supernatants were incubated with the purified CHK-SH2 fusion protein
(Fig. 2, A and B) or with the 3E8 monoclonal
antibody to ErbB-2 (Fig. 2, C and D). The
co-precipitated proteins were analyzed on 7% SDS-PAGE, and
immunoblotted with PY20 (Fig. 2, A and C). As
shown in Fig. 2A, a tyrosine-phosphorylated 185-kDa protein
was associated with CHK-SH2 within 2 min of the HRG stimulation. The
association of the 185-kDa protein with CHK-SH2 was maximal at 2-8 min
after HRG stimulation and then gradually decreased. In order to
determine whether the 185-kDa protein was ErbB-2, the blot was deprobed and reblotted with polyclonal anti-ErbB-2 antibody. As shown in Fig.
2B, the 185-kDa protein was confirmed to be the ErbB-2
protein. These results indicated that the CHK protein can interact with the HRG-activated ErbB-2 receptor.
When lysates from HRG-treated cells were immunoprecipitated with the 3E8 monoclonal anti-ErbB-2 antibody, the pattern of the phosphorylated ErbB-2 was different from that of the ErbB-2 precipitated with the SH2 domain of CHK (compare Fig. 2C with Fig. 2A). Blotting of the same samples with the polyclonal anti-ErbB-2 antibody (Fig. 2D) confirmed these observations. This difference might indicate that tyrosine phosphatase(s) are involved in the association of CHK with the activated ErbB-2.
CHK-SH2 fusion proteins also precipitated other as yet unidentified tyrosine-phosphorylated proteins, as shown in Fig. 2A. However, these phosphorylated proteins were also precipitated from the unstimulated cells, and their phosphorylation pattern did not appear to change over the time course of these studies.
The Association of CHK with ErbB-2 Is Specific for HRG StimulationIn order to determine whether the observed
association of CHK with ErbB-2 was receptor-specific and
stimulus-specific, we analyzed whether CHK could associate with either
the EGF-R or IL-6 receptors, which are both known to be expressed in
T47D cells (1, 59). We compared the association of CHK-SH2 with ErbB-2 in lysates from HRG, EGF, and IL-6-stimulated cells (Fig.
3). T47D cells were serum-starved as described above and
then activated either with HRG (10 nM) for 8 min or with
EGF (100 ng/ml) or IL-6 (100 ng/ml) for 5 min. The experimental time
points and the concentrations of EGF and IL-6 were optimized in initial
kinetic studies (data not shown). The stimulated cells were lysed and
precipitated with the CHK-SH2 fusion protein as described above. The
precipitates were then analyzed on SDS-PAGE and immunoblotted with PY20
antibodies or with polyclonal anti-ErbB-2 antibodies. Only HRG
stimulation induced the association of ErbB-2 with the purified CHK-SH2
fusion protein. EGF or IL-6 stimulation failed to induce CHK-SH2
association to ErbB-2 (Fig. 3), to the EGF receptor, or to the IL-6
receptor (data not shown).
The association of ErbB-2 with other SH2 domain-containing signaling
molecules such as p85 of PI 3-kinase, phospholipase C-1 (Fig.
3A), or Shc was also examined. The SH2-SH2-SH3 domain of phospholipase C-
1 was found to be associated with the HRG-activated ErbB-2 (Fig. 3A) as well as with Shc (data not shown). The
SH2 domain of PI 3-kinase precipitated ErbB-2, probably as a result of
the ErbB-2 heterodimerization with ErbB-3 (60). Taken together, these
results indicate that ErbB-2 associates with all three signaling molecules in HRG-activated T47D cells.
The potential involvement of other domains of CHK in
the interaction with ErbB-2 was examined. GST fusion proteins
containing the SH3 domain of CHK (CHK-SH3), the N-terminal domain plus
SH3 domain (NH2-SH3), the SH3 and SH2 domains of CHK
(SH3-SH2), and the SH2 domain of CHK as well as the GST protein alone
were prepared as described under "Experimental Procedures."
HRG-stimulated T47D cell lysates were incubated with the different GST
fusion proteins, analyzed by SDS-PAGE, and immunoblotted with PY20,
rabbit anti-ErbB-2 antibody, or with anti-GST antibody (Fig.
4). Neither the SH3 domain of the CHK protein nor the
NH2-SH3 domain precipitated ErbB-2 (Fig. 4A).
Binding to ErbB-2 was detected only in the presence of the CHK-SH2
(data not shown) and CHK-SH3-SH2 fusion proteins (Fig. 4B).
As expected, no binding was detected when the same lysates were
incubated with the GST protein alone. The amounts of the different
fusion proteins loaded on the gel were comparable (as shown in Fig.
4C). Therefore, we conclude that CHK can interact with the
HRG-stimulated ErbB-2 in a specific manner via its SH2 domain.
In Vivo Association of Intact CHK with ErbB-2
To further
confirm the association of ErbB-2 with CHK, we overexpressed the CHK
protein in MCF-7 breast cancer cells. CHK expression in MCF-7 cells was
detected only by PCR analysis (data not shown). Expression of the ErbB
receptor family in MCF-7 cells was similar to that observed in T47D
cells. Stable transfections were performed using the Flag-CHK
pCDNA3-neo construct as described under "Experimental
Procedures." The transfected cells were analyzed for CHK expression
by Western blot using anti-Flag and anti-CHK antibodies and also by
immunofluorescence using confocal microscopy (data not shown). MCF-7
cells transfected with Flag-CHK pCDNA3-neo (Flag-CHK), MCF-7 cells
transfected with the pCDNA3-neo vector alone, or untransfected
MCF-7 control cells were stimulated with HRG and then lysed. The
lysates were immunoprecipitated with anti-Flag antibodies (data not
shown) and anti-CHK antibodies, and the associated proteins were
analyzed by SDS-PAGE and immunoblotted with PY20 or polyclonal
anti-ErbB-2 antibody (Fig. 5). The 185-kDa
tyrosine-phosphorylated protein was immunoprecipitated with anti-Flag
antibodies (data not shown) or anti-CHK antibodies only in
HRG-stimulated Flag-CHK-transfected cell lysates (Fig. 5A)
but not in the untransfected MCF-7 cell lysates (Fig. 5A) or
the MCF-7 cell lysates transfected with the pcDNA3-neo Flag vector
alone (data not shown). Blotting with the anti-ErbB-2 antibody
confirmed that the co-precipitated 185-kDa protein was indeed the
ErbB-2 (Fig. 5B). Analysis of the total lysates from the
same experiment revealed that the ErbB-2 was tyrosine-phosphorylated as
a result of the HRG stimulation in the Flag-CHK cells as well as in the
MCF-7 untransfected cells (Fig. 5C). The expression of
ErbB-2 appeared to be equal in both the Flag-CHK and MCF-7 cells (Fig.
5D). Taken together, these in vitro and in
vivo data indicate that the HRG-stimulated ErbB-2 associates with
CHK through the SH2 domain.
Involvement of Other ErbB Family Members in the Interaction with CHK
To further investigate the possible involvement of other
members of the ErbB family in the observed interaction between CHK and
ErbB-2, we performed co-immunoprecipitation experiments using MCF-7
cells transfected with Flag-CHK. Flag-CHK-transfected cells were
stimulated with HRG and then lysed and immunoprecipitated with anti-CHK
antibody. The immunocomplexes were separated by SDS-PAGE and
immunoblotted with anti-ErbB-2 antibody (Fig.
6A) or with anti-ErbB-3 antibody (Fig.
6B). The results indicated that anti-CHK antibody
immunoprecipitated the HRG-activated ErbB-2. In contrast, no detectable
ErbB-3 was found. However, the possibility that very low amounts of
ErbB-3 were present in the precipitates as a result of the
heterodimerization with the ErbB-2 receptor upon HRG stimulation cannot
be excluded. We also investigated whether ErbB-4 interacted with CHK
under these conditions; however, our findings indicated that ErbB-4 was
not involved in the ErbB-2-CHK association (data not shown).
In order to confirm the presence and phosphorylation of the ErbB-3 as well as the heterodimerization of ErbB-3 with ErbB-2 in the Flag-CHK-transfected cells, lysates from HRG-stimulated Flag-CHK cells were immunoprecipitated with anti-ErbB-3 antibodies or with anti-ErbB-2 antibodies. Both ErbB-3 and ErbB-2 were tyrosine-phosphorylated upon HRG stimulation (Fig. 6C), and the formation of ErbB-2-ErbB-3 heterodimers was demonstrated by the presence of ErbB-2 in the precipitates of the anti-ErbB-3 antibodies (Fig. 6D). However, under these conditions, we could not detect ErbB-3 in the samples immunoprecipitated with anti-ErbB-2 antibody. Taken together, these observations indicate that upon HRG stimulation, heterodimerization of ErbB-3 with ErbB-2 receptors occurred in the transfected cells, suggesting that the ErbB signaling in these cells is not altered.
To determine whether EGF-R (ErbB-1) might be involved in ErbB-2-CHK
interactions, Flag-CHK MCF-7-transfected cells were serum-starved and
then stimulated with HRG (10 nM) or with EGF (100 ng/ml). The lysates were immunoprecipitated with anti-CHK antibodies and analyzed by SDS-PAGE. Only the tyrosine-phosphorylated ErbB-2 protein
was immunoprecipitated with anti-CHK-antibodies in the HRG-stimulated
lysates (Fig. 7, A and B). No
tyrosine-phosphorylated proteins were detected in the
immunoprecipitates with anti-CHK antibodies from the EGF-stimulated
cells (Fig. 7C). Reprobing of this blot in Fig.
7C with anti-ErbB-2 (data not shown) or with anti-EGF-R
(Fig. 7D) antibodies confirmed that neither of these receptors was present in the CHK immunoprecipitates. As a control, we
performed immunoprecipitations with anti-EGF-R antibodies of the
EGF-stimulated Flag-CHK cell lysates as well as of lysates from
untransfected MCF-7 cells. The EGF-R and the ErbB-2 proteins were
present in the immunoprecipitates from the EGF-stimulated cells (not
shown) as a result of the EGF-ErbB-2 heterodimerization. Probing of the
same blot with anti-ErbB-2 or anti-EGF-R antibodies confirmed this
observation (data not shown).
These analyses indicate that CHK associates via its SH2 domain with HRG-stimulated ErbB-2. This association is specific to HRG-stimulated ErbB-2 and does not appear to prominently involve other ErbB family members.
In this report, we have shown the interaction of CHK, a recently identified cytoplasmic protein-tyrosine kinase, with ErbB-2 upon the activation of breast cancer cells by HRG. This interaction occurred via the SH2 domain of CHK and was specific to the activated ErbB-2 receptor upon HRG stimulation.
CHK was recently cloned, and its expression pattern was characterized by us and by others (43-52). CHK is highly restricted in expression in normal tissues of brain and hematopoietic cells. Recently, we have observed that CHK interacts in a specific and SH2-dependent manner with the c-Kit receptor and participates in the c-Kit signaling pathway in human megakaryocytes (45). Our observation of CHK expression in breast cancer tissues suggests that CHK might be involved in signaling in some cases of breast cancer.
In this report, we demonstrated the association of the SH2 domain of CHK with the HRG-activated ErbB-2 receptor using GST fusion proteins containing different domains of the CHK molecule. Other domains, such as the SH3 domain or the NH2-terminal region of CHK did not appear to be required for the association of CHK with ErbB-2 (Fig. 4). The CHK-ErbB-2 interaction occurred upon the HRG-induced phosphorylation of ErbB-2 (Fig. 2). After 10 min of HRG stimulation, binding of ErbB-2 to the CHK-SH2 domain decreased gradually, while the immunoprecipitated ErbB-2 with anti-ErbB-2 antibodies from the same lysates seemed to remain phosphorylated. This difference in the binding pattern of ErbB-2 to CHK-SH2 as compared with anti-ErbB-2 antibodies could stem from the higher accessibility of the CHK recognition site in the ErbB-2 receptor to tyrosine phosphatases, compared with other tyrosine residues in the ErbB-2 receptor. These observations might indicate a possible regulation and involvement of tyrosine phosphatase(s) in the association of CHK and activated ErbB-2.
In this study, we also addressed the receptor ligand specificity of the observed association between CHK and ErbB-2. Neither EGF nor IL-6 induced the association of CHK with ErbB-2 (Fig. 3) in T47D cells, although treatment of the same cells with EGF did cause the tyrosine phosphorylation of ErbB-2 by heterodimerization as previously reported (1, 24, 26, 28, 61). It is possible that the binding site of CHK on the ErbB-2 receptor is not trans-phosphorylated by the EGF receptor. This might also explain the difference of cell response to binding of EGF versus HRG to heterodimers that contain ErbB-2 and EGF-R, ErbB-2 and ErbB-3 or ErbB-4. For example, it has been shown that ErbB-2 alone or in combination with EGF-R resulted in the malignant transformation of murine fibroblasts (34, 62, 63), while HRG affected both mitogenesis and differentiation in different mammary tumor cells (62, 64-67).
The SH2 domain of CHK was found to interact specifically with ErbB-2, while no interaction was observed between CHK with either IL-6 receptor or EGF-R (Fig. 3). In addition, neither ErbB-3 nor ErbB-4 was detected in the precipitates of the GST-SH2 fusion proteins of CHK (data not shown).
To analyze the association of CHK with ErbB-2 in vivo, we performed co-immunoprecipitation studies of ErbB-2 using anti-CHK antibodies (Fig. 5). The co-immunoprecipitation of ErbB-2 with CHK occurred upon HRG stimulation in the presence of CHK in Flag-CHK MCF-7 transfected cells, but not in untransfected MCF-7 cells or cells transfected with the vector alone. These observations suggest that the association of ErbB-2 with CHK occurs in vivo in those breast cancer cells that express CHK.
The possible involvement of other ErbB family members in the CHK-ErbB-2 association was also analyzed by co-immunoprecipitation studies. Upon HRG stimulation, no detectable amounts of either ErbB-3 or ErbB-4 were found in transfected cells immunoprecipitated with anti-CHK antibodies (Fig. 6). We also could not detect any EGF-R molecules in the EGF-stimulated Flag-CHK-transfected cell lysates that were immunoprecipitated with the anti-CHK antibodies (Fig. 7).
The results presented here suggest that CHK can interact only with one
member of the ErbB family, ErbB-2. ErbB-2, through its own set of
docking sites for SH2-containing proteins, may diversify the nature of
the intracellular signals generated by HRG and EGF. The specificity of
ErbB family members to various downstream signaling molecules has been
previously demonstrated. EGF-R and ErbB-2 have been shown to interact
with phospholipase C-1 and GTPase-activating protein, while ErbB-3
does not interact with those two molecules (60, 39). However, ErbB-3 is
the main ErbB family member that has been shown to interact with PI 3-kinase (39). ErbB-3 may thus play a role in coupling PI 3-kinase to
other ErbB family receptor molecules (68, 69). Similar relationships
have been demonstrated for the insulin receptor substrate-1, the
insulin receptor, and the insulin-like growth factor I-receptor (68,
70, 71). Insulin receptor substrate-1 was shown to function as an
accessory protein to the insulin receptor involved in the recruitment
and activation of PI 3-kinase (68). Similarly, CD19, a membrane protein
found in B cells, also has a PI 3-kinase binding site to which membrane
IgM can be coupled (68, 72).
To our knowledge, no similar interactions between CHK or Csk and the ErbB family receptors have been reported to date. Recently, the sites where CHK binds to the c-Kit receptor have been identified in our laboratory (73). Comparison of these sites to the five autophosphorylated sites in the ErbB-2 receptor did not reveal any shared identities. Interestingly, one of the three proposed binding sites of CHK to the c-Kit receptor is known to bind the p85 regulatory subunit of PI 3-kinase (73). Similar sites exist within EGF-R and ErbB-2, but they do not appear to be autophosphorylated. Others have recently reported that EGF-R as well as ErbB-2 are phosphorylated by c-Src at nonautophosphorylation sites and that these novel sites can act as docking sites for Src, p85 of PI 3-kinase, and potentially other SH2-containing proteins (74).
In addition to sequence homology, CHK and Csk also share functional properties. Like Csk, CHK was also shown to phosphorylate purified Src protein in vitro (44, 45, 53-57). Therefore, CHK might act as a negative regulator of Src kinase activity. Interestingly, Src kinase has been reported to be directly associated with, and activated by, the ErbB-2 receptor (37-38, 75). In light of these findings, future studies will aim to characterize the involvement of CHK in Src-ErbB receptor family signaling.
Recently, ErbB-2 has been proposed to act as a modulating subunit of the ErbB family receptors by serving as an essential common subunit of the receptors for HRG and EGF (62). This function is similar to the non-ligand binding components of the interleukin receptors; e.g. gp130 is shared by the receptors for IL-6, leukemia inhibitory factor, oncostatin M, IL-11, and ciliary neurotrophic factor (76). Overexpression of ErbB-2 has been shown to enhance the binding affinity to both EGF and neu differentiation factor through deceleration of ligand dissociation rates (62). Likewise, the removal of ErbB-2 from the cell surface almost completely abolished ligand binding by accelerating the dissociation of both growth factors (62), resulting in an impairment of both HRG and EGF signaling (1, 9, 62). Here we propose an additional modulating role for the ErbB-2 receptor; by interacting with CHK, ErbB-2 recruits CHK within the proximity of its potential substrate, Src, which can be associated with the cytoplasmic domain of another ErbB family member present in a given heterodimer. CHK-ErbB-2 association may lead to the down-regulation of Src activity through its phosphorylation by CHK and hence the attenuation of the receptor signal. Future studies will seek to experimentally assess this model in the context of breast cancer proliferation.
This paper is dedicated to Charlene Engelhard for her friendship and support for our research program.