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J. Biol. Chem., Vol. 275, Issue 24, 18581-18585, June 16, 2000
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From the Department of Molecular Genetics and Biochemistry,
University of Pittsburgh School of Medicine,
Pittsburgh, Pennsylvania 15261
Received for publication, February 25, 2000, and in revised form, April 13, 2000
Bcr-Abl is the constitutively active
protein-tyrosine kinase expressed as a result of the Philadelphia
translocation in chronic myelogenous leukemia. Bcr-Abl is coupled to
many of the same signaling pathways normally regulated by hematopoietic
cytokines. Recent work shows that Hck, a member of the Src tyrosine
kinase family with myeloid-restricted expression, associates with and
is activated by Bcr-Abl. Here we investigated the mechanism of Hck
interaction with Bcr-Abl and the requirement for Hck activation in
Bcr-Abl transformation signaling. Binding studies demonstrated that the Hck SH3 and SH2 domains are sufficient for interaction with Bcr-Abl in vitro. Hck binding localizes to the Abl SH2, SH3, and
kinase domains as well as the distal portion of the C-terminal tail. To
address the requirement for endogenous Src family kinase activation in
Bcr-Abl signaling, a kinase-defective mutant of Hck was stably expressed in the cytokine-dependent myeloid leukemia cell
line DAGM. Kinase-defective Hck dramatically suppressed Bcr-Abl-induced outgrowth of these cells in the absence of cytokine compared with a
control cell line expressing Several human leukemias are characterized by the presence of the
Philadelphia chromosome which results from the translocation of the
c-abl locus on chromosome 9 and the bcr locus
chromosome 22 (reviewed in Refs. 1 and 2). This translocation results in the expression of a family of chimeric Bcr-Abl oncoproteins associated with specific leukemias (3-6). Chronic myelogenous leukemia
(CML)1 results from the
210-kDa form of Bcr-Abl (p210), while acute lymphocytic leukemia (ALL)
is associated with a 185-kDa form (p185) (7, 8). Both forms of Bcr-Abl
are constitutively active protein-tyrosine kinases that have been shown
to transform cells in culture and to produce CML- and ALL-like
syndromes in transgenic mice, providing strong evidence that Bcr-Abl is
responsible for the development of these leukemias (9-11).
Bcr-Abl has been shown to activate multiple signal transduction
pathways normally associated with the growth, survival, and differentiation of hematopoietic cells. For example,
tyrosine-phosphorylated Bcr-Abl can interact directly with the
Grb-2/Sos guanine nucleotide exchange factor, leading to the activation
of Ras (12, 13). Bcr-Abl can also activate Ras via Shc, an adaptor
protein that couples the receptors for many growth factors and
cytokines to the Grb2/Sos complex (14). Other work has identified Crk-L
as a binding partner and substrate for Bcr-Abl (15, 16). Crk-L may
couple Bcr-Abl to the guanine-nucleotide exchange factor C3G, providing
an additional connection to Ras activation (17). In addition to the Ras
pathway, Bcr-Abl is coupled to PI-3K signaling and activation of
Akt/PKB kinases downstream (18). This pathway may promote
cytokine-independent survival by Bcr-Abl (19, 20). Other studies have
demonstrated that Bcr-Abl induces activation of Stat transcription
factors, which have also been implicated in proliferative and survival
signaling in a wide variety of hematopoietic cell types (21-24). All
of these signaling pathways involve components with SH2 and SH3 domains
and are dependent upon tyrosine phosphorylation.
Although Bcr-Abl possesses a constitutively active tyrosine kinase
domain, recent work suggests that it may initiate signaling by
activating other nonreceptor tyrosine kinases, including members of the
Fps/Fes and Src families (25-28). Regarding the Src family, Bcr-Abl
has been shown to associate directly with Lyn and Hck in 32Dcl3 cells.
This interaction correlates with increased Lyn and Hck tyrosine kinase
activity (25). More recently, Hck has been shown to phosphorylate p210
Bcr-Abl on Tyr 177, the site responsible for direct recruitment of
Grb-2/Sos through the Grb-2 SH2 domain (26). This result suggests that
Src family kinases may facilitate the coupling of Bcr-Abl to Ras and
other signaling pathways related to transformation. In this study, we
investigated the mechanism of Hck interaction with Bcr-Abl. We observed
that the Hck SH2 and SH3 domains bind strongly to recombinant Bcr-Abl in vitro. Constitutive binding was observed with the SH3
domain, while SH2-mediated binding was found to require Bcr-Abl
autophosphorylation. In reciprocal experiments, we observed that
multiple regions of Abl, including the SH3, SH2, and kinase domains as
well as the distal portion of the C-terminal region interact directly
with Hck. We also found that a kinase-inactive mutant of Hck strongly suppressed Bcr-Abl proliferative signals in
cytokine-dependent myeloid leukemia cells, suggesting that
activation of Hck or other members of the Src kinase family is required
for Bcr-Abl transformation signaling. Activation of Src family kinases
by Bcr-Abl may contribute to the diversity of signaling pathways
activated by this transforming tyrosine kinase.
GST-Hck Fusion Protein Binding Assay--
Construction of
pGEX-2T vectors and expression of the noncatalytic regions of Hck as
GST fusion proteins is described elsewhere (29). Briefly,
Escherichia coli DH5 Co-precipitation of Abl Domains and Hck in Sf-9 Cells--
The
coding sequences for the human Abl SH3 and SH2 domains
(Gly57-Thr224) and kinase domain
(Tyr215-Ile489) were amplified by polymerase
chain reaction and subcloned into the baculovirus transfer vector
pVL-GST (30). The C-terminal region of Abl was similarly amplified as a
series of four sequences encoding residues
Pro480-Gly638 (CT1),
Arg639-Leu813 (CT2),
Ile801-Ala993 (CT3), and
Gly994-Arg1130 (CT4), which were subcloned
into the same vector. The resulting pVL-GST constructs were used to
create recombinant baculoviruses for the expression of these Abl
regions as GST fusion proteins. Sf-9 cells (2.5 × 106) were co-infected with each of the GST-Abl
baculoviruses (or a GST baculovirus as a negative control) and an Hck
baculovirus. Forty-eight h postinfection, the cells were lysed in 1.0 ml of Hck lysis buffer, and GST fusion proteins were precipitated with glutathione-agarose beads (Sigma; 20 µl of a 50% w/v suspension). The precipitates were washed three times with 1.0 ml of RIPA buffer, and bound proteins were eluted by heating in SDS-PAGE sample buffer. Proteins were resolved on duplicate SDS-polyacrylamide gels and transferred to polyvinylidene difluoride membranes. Associated Hck was
visualized by immunoblotting with Hck polyclonal antibodies (Santa
Cruz). The amount of precipitated GST-Abl fusion protein present in
each reaction was determined by immunoblotting with anti-GST antibodies
(Santa Cruz). Equivalent expression of Hck in each culture was verified
by immunoblot analysis of the clarified cell lysates. The relative
amount of bound Hck and GST-Abl fusion protein present in each lane was
determined by densitometry (Bio-Rad GS-710 Imaging Densitometer), and
the amount of Hck bound was corrected to the amount of GST-Abl fusion
protein present in each sample.
Retroviral Constructs--
Subcloning of the Hck wild-type and
kinase-inactive (Hck-KE) cDNAs into the retroviral expression
vector pSR DAGM Cell Proliferation Assays--
DAGM myeloid leukemia cells
(14) were cultured in RPMI 1640 medium containing 10% fetal bovine
serum, 50 µg/ml gentamycin, and 2.5 ng/ml IL-3. Cells were infected
with The Hck SH2 and SH3 Domains Bind Directly to Bcr-Abl in
Vitro--
Previous studies have shown that Bcr-Abl forms a complex
with endogenous Hck and Lyn in 32Dcl3 myeloid leukemia cells and that
interaction correlates with activation of these Src family kinases
(25). To determine the molecular basis for this interaction, we
expressed a family of GST fusion proteins containing each of the
noncatalytic domains of Hck (N-terminal, SH3, and SH2 either alone or
in various combinations) in E. coli and immobilized them on
glutathione-agarose beads. Equal amounts of each fusion protein were
incubated with lysates from Sf-9 cells expressing the p210 form of
Bcr-Abl, a kinase-defective form of p210 (p210-KR) or the p185 form of
Bcr-Abl. Protein complexes were collected by centrifugation, washed,
and associated Bcr-Abl was visualized by immunoblotting. As shown in
Fig. 1, fusion proteins containing the
Hck SH2 or SH3 domains readily precipitated both p210 and p185 Bcr-Abl.
In contrast, no binding was detected with a GST fusion protein of the
unique N-terminal region of Hck, GST alone, or the glutathione-agarose
resin.
To test for the dependence of these interactions on Bcr-Abl tyrosine
phosphorylation, a similar experiment was conducted with extracts from
Sf-9 cells expressing the kinase-defective form of p210 Bcr-Abl. As
shown in Fig. 1, this mutant was unable to bind to the isolated Hck SH2
domain, strongly suggesting that autophosphorylation of Bcr-Abl creates
a specific binding site for the SH2 domain of Hck. In contrast, the
kinase-defective mutant bound to the fusion proteins containing the SH3
domain to the same extent as kinase-active Bcr-Abl, as expected for an
SH3-mediated interaction. These results indicate that multiple docking
sites for Src family kinases exist within Bcr-Abl. Recent studies have shown that SH3 and SH2 engagement is sufficient to activate Src kinases
in a variety of cellular contexts. The SH2/SH3-mediated interaction of
Hck with Bcr-Abl may provide a mechanistic basis for previous reports
of Hck activation by Bcr-Abl in vivo (see "Discussion").
Multiple Regions of Abl Contribute to Interactions with
Hck--
To identify the regions of Bcr-Abl that interact with Hck, a
series of GST-Abl fusion proteins was co-expressed with wild-type Hck
in Sf-9 cells. The primary structures of these GST-Abl fusion proteins
are shown in Fig. 2 and include the
SH3/SH2 region, the kinase domain, and the long C-terminal tail as a
series of four fusion proteins. The GST-Abl proteins were precipitated
from infected cell lysates with glutathione-agarose beads, and
associated Hck was visualized by immunoblotting. As shown in Fig.
3, several regions of Abl bound
independently to Hck, including the SH3/SH2 region, the kinase domain,
and the distal portion of the C-terminal tail. Hck did not bind to the
Abl C-terminal fusion proteins containing proline-rich sequences
involved in SH3 binding to the Crk-L adaptor protein (16). These
results indicate that Hck interacts with the Abl portion of Bcr-Abl
through multiple sites that may include a novel interaction with the
C-terminal actin-binding domain (see "Discussion").
Kinase-defective Hck Inhibits Transformation of DAGM Cells to
Cytokine Independence--
Previous studies have demonstrated a direct
interaction of Bcr-Abl with Hck and Lyn in myeloid leukemia cells,
suggesting that activation of Src kinases may contribute to Bcr-Abl
signaling (25). To determine whether interaction with endogenous Src
kinases is required for Bcr-Abl signal transduction, we tested the
effect of kinase-inactive Hck on Bcr-Abl-induced transformation of the IL-3-dependent myeloid leukemia cell line, DAGM.
Introduction of Bcr-Abl into these cells with a recombinant retrovirus
has been shown to result in cytokine-independent proliferation (14). DAGM cells were infected with recombinant retroviruses carrying either
the kinase-defective form of Hck (Hck-KE) or
To determine whether expression of kinase-defective Hck produced a
general suppression of proliferative capacity, the populations of DAGM
cells expressing Hck-KE as well as the
In a final control experiment, we examined whether overexpression of
wild-type Hck affected p210 Bcr-Abl-induced conversion of DAGM cells to
cytokine independence. Cell populations were produced which stably
expressed Data presented in this paper provide new mechanistic insight
regarding the association of Src family kinases with Bcr-Abl and show
for the first time that these interactions may be required for Bcr-Abl
transformation signaling. Regarding the mechanism of interaction,
binding assays demonstrate that the SH2 and SH3 domains of Hck are
sufficient to bind Bcr-Abl in vitro (Fig. 1). SH2-dependent binding occurs through a
phosphotyrosine-dependent mechanism, as a kinase-defective
mutant of Bcr-Abl was unable to bind to the Hck SH2 domain. These data
suggest a mechanism to explain previous observations that interaction
with Bcr-Abl activates Hck and Lyn (25). Binding of Src family kinases
to other proteins through their SH2 and/or SH3 domains is often
sufficient for activation. For example, the SH3-dependent
interaction of Hck with the Nef protein of HIV-1 leads to Hck
activation and transformation of Rat-2 fibroblasts (32, 36). This
effect is due to the ability of Nef to displace the SH3 domain of Hck from an intramolecular interaction with the linker connecting the SH2
and kinase domains (37). Together with intramolecular binding of the
tyrosine-phosphorylated tail region to the SH2 domain, SH3-linker
interaction is a key part of negative regulation of Src family kinases
(38). Binding of Hck or other Src kinases to Bcr-Abl through their SH3
and SH2 domains may result in kinase activation though a similar
mechanism involving disruption of intramolecular regulatory interactions.
Three regions within the Abl portion of Bcr-Abl demonstrated strong
interactions with Hck, including the SH3/SH2 region, the kinase domain,
and the distal portion of the C-terminal tail. Binding of the Abl
SH3/SH2 region to Hck may occur through sites of Hck tyrosine
autophosphorylation and/or the polyproline linker connecting the SH2
and kinase domains. Interaction of the Abl SH3 domain with the Hck
linker could contribute to Hck activation by disturbing intramolecular
SH3-linker interactions as described above. Interestingly, the SH2/SH3
region of Bcr-Abl has recently been shown to play a role in the
activation of Stat5, although direct interaction of Bcr-Abl with Stat5
does not occur to a significant extent (24). Our observation that the
SH3/SH2 region of Bcr-Abl is involved in the recruitment of Hck
suggests that Src kinases may serve as intermediates linking Bcr-Abl to
Stat5 activation and downstream survival signaling.
Interaction experiments involving the Abl C-terminal region also
produced unexpected results. Fusion proteins encompassing the
C-terminal regions of Abl with known SH3-binding sites for other
proteins such as Crk-L did not interact strongly with Hck (Figs. 2 and
3). On the other hand, the fusion protein containing the C-terminal 137 amino acids of Abl (CT4) associated strongly with Hck, despite the lack
of tyrosine phosphorylation or an obvious PxxP motif. This region of
Abl encompasses the F-actin binding domain and is required for Bcr-Abl
transforming activity (39-41). Whether or not this region also
contributes to interactions with Src-related kinases in vivo
will require further study.
In addition to investigating the mechanism of Bcr-Abl interaction with
Src kinases, we also present evidence that activation of Hck or other
Src family members may be required for transformation signaling by
Bcr-Abl in myeloid cells. Co-expression of Bcr-Abl with a
kinase-defective mutant of Hck strongly suppressed both p185 and p210
Bcr-Abl signals for cytokine-independent outgrowth of the DAGM myeloid
leukemia cell line (Fig. 4). This result is consistent with the binding
data shown in Fig. 1, as both forms of Bcr-Abl demonstrated equivalent
binding to the SH2 and SH3 domains of Hck. In contrast,
kinase-defective Hck had no effect on cytokine-induced cell outgrowth,
arguing against a nonspecific effect of Hck on cellular proliferation
(Fig. 5). These results suggest that the kinase-defective mutant of Hck
interacts directly with Bcr-Abl and competes for association with
endogenous Src family kinases, resulting in the observed suppression of
DAGM cell proliferation. The partial suppressive effect of wild-type Hck in this system (Fig. 6) suggests that activation of more than one
Src kinase family member may contribute to survival and proliferative signaling. Overexpression of wild-type Hck may compete for activation of other Src family members required for a complete biological signal,
while maintaining the signal from Hck. Consistent with this idea is the
observation that Lyn and Fyn associate with the same regions of Bcr-Abl
as Hck in vitro (data not shown). Previous studies have
shown that kinase-defective and other Src mutants can interfere with
growth factor and cytokine signal transduction and block growth factor
induced entry into the cell cycle in some cases (reviewed in Ref. 42).
Whether or not Src kinases are required to couple Bcr-Abl to
proliferative and survival signaling pathways during the development of
CML will require further investigation.
We thank Dr. Owen Witte, Howard Hughes Medical
Institute, UCLA for the Bcr-Abl cDNA clones, retroviral vectors,
and the DAGM cell line.
*
This work was supported by National Institutes of Health
Grant CA81398 and American Cancer Society Grant RPG-96-052-04-TBE.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
To whom correspondence should be addressed: Dept. of Molecular
Genetics and Biochemistry, University of Pittsburgh School of Medicine,
E1240 Biomedical Science Tower, Pittsburgh, PA 15261. Tel.:
412-648-9495; Fax: 412-624-1401; E-mail: tsmithga@pitt.edu.
Published, JBC Papers in Press, April 14, 2000, DOI 10.1074/jbc.C000126200
The abbreviations used are:
CML, chronic
myelogenous leukemia;
ALL, acute lymphocytic leukemia;
PAGE, polyacrylamide gel electrophoresis;
GST, glutathione
S-transferase;
IL, interleukin;
ACCELERATED PUBLICATION
Transformation of Myeloid Leukemia Cells to Cytokine Independence
by Bcr-Abl Is Suppressed by Kinase-defective Hck*
,
ABSTRACT
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-galactosidase. In contrast,
kinase-defective Hck did not affect cell proliferation in response to
interleukin-3, suggesting that the effect is specific for Bcr-Abl.
These data show that Hck interacts with Bcr-Abl through a complex
mechanism involving kinase-dependent and -independent
components and that interaction with Hck or other Src family members is
essential for transformation signaling by Bcr-Abl.
INTRODUCTION
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were transformed with pGEX-Hck constructs, and GST fusion protein expression was induced with isopropyl--D-thiogalactopyranoside. Following induction,
recombinant fusion proteins were isolated from clarified cell extracts
with glutathione-agarose beads. The concentration of each protein was determined on Coomassie-stained gels by two-dimensional laser densitometry using bovine serum albumin as a standard. For the binding
reactions, wild-type and kinase-defective forms of Bcr-Abl were
expressed in Sf-9 insect cells using recombinant baculoviruses as
described elsewhere (28). Immobilized GST fusion proteins (20 µg) or
GST alone as a negative control were added to 1 ml aliquots of
clarified Sf-9 cell lysates and rotated at 4 °C for 2 h. Fusion
proteins were pelleted by centrifugation and washed once with 1.0 ml
Hck lysis buffer (50 mM Tris-HCl, pH 7.4, 50 mM
NaCl, 1 mM EDTA, 10 mM MgCl2, 1%
Triton X-100) followed by three washes with RIPA buffer (50 mM Tris-HCl, pH 7.4, 50 mM NaCl, 1 mM EDTA, 10 mM MgCl2, 1% Triton
X-100, 1% sodium deoxycholate, 0.1% SDS). Precipitated proteins were
solubilized in SDS-PAGE sample buffer and associated Bcr-Abl was
detected by immunoblotting.
MSVtkneo (31) has been described elsewhere
(32). The coding sequence for bacterial -galactosidase was subcloned
from the expression vector pCMVSport (Life Technologies, Inc.) into
pSRMSVtkneo. Similar pSRMSVtkneo constructs
containing the coding sequences for the p210 and p185 forms of Bcr-Abl
were obtained from Dr. Owen Witte, Howard Hughes Medical Institute,
UCLA. To make retroviral stocks, subconfluent 100-mm dishes of 293T
cells were transfected with 30 µg of each retroviral construct and an
ecotropic packaging vector using the calcium phosphate method described
elsewhere (32-34). Viral supernatants were collected 48, 72, and
96 h posttransfection, pooled, filtered with 0.45-µm filters,
and stored at 
80 °C.
-gal or Hck retroviruses and selected with G-418 at 800 µg/ml. Expression of Hck proteins in the drug-resistant cell
populations was verified by immunoblotting. Hck and -gal control
cells were then superinfected with Bcr-Abl or -gal control
retroviruses as follows: 106 cells were resuspended in 5 ml
of viral supernatant in the presence of 4 µg/ml polybrene. To enhance
retroviral gene transfer, culture plates were centrifuged at 2,400 rpm
for 4 h at 20 °C (35). The virus was replaced with fresh medium
containing G-418 and IL-3 and the cultures incubated for 72 h. For
analysis of IL-3-independent outgrowth, cells were washed free of
cytokine and 4 × 104 cells were plated in 100 µl of
complete medium in each well of a 96-well plate. To quantitate cell
outgrowth, cells in each well were combined with 25 µl of MTT reagent
(5 mg/ml in H2O) and incubated for 4 h at 37 °C.
The reaction was stopped by adding 100 µl of MTT lysis buffer (50%
N,N-dimethylformamide in H2O
containing 20% SDS, 2.5% glacial acetic acid, and 2.5% 1 N HCl, pH 4.7). Plates were incubated overnight at
37 °C, and the absorbance of each well was read at 570 nm. Positive
controls were analyzed in a similar manner in the presence of IL-3. For
all plates, a well containing only culture medium and no cells served
as a background control for the absorbance readings.
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Fig. 1.
Association of the Hck noncatalytic region
with Bcr-Abl in vitro. The noncatalytic domains
of Hck (unique N-terminal, SH3 and SH2) were expressed either alone or
in the combinations shown in A as GST fusion proteins in
E. coli and immobilized on glutathione-agarose beads.
B, the immobilized fusion proteins, GST alone, or the
glutathione-agarose resin (GSH) were mixed with lysates from
Sf-9 cells expressing the p210 form of Bcr-Abl (p210), a
kinase-defective mutant of p210 (p210-KR), or the p185 form of Bcr-Abl
(p185). Following incubation and washing, bound Bcr-Abl proteins were
visualized by immunoblotting. Control blots of the Sf-9 cell lysates
showed Bcr-Abl bands of identical electrophoretic mobilities and
comparable intensities as the pull-down result (data not shown).
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Fig. 2.
Structures of GST-Abl fusion proteins.
Recombinant baculoviruses were constructed for expression of the Abl
SH3/SH2 region (Gly57-Thr224; human c-Abl
numbering) and the kinase domain
(Tyr215-Ile489) as GST fusion proteins in Sf-9
cells. Baculoviruses for the expression of the C-terminal region of Abl
were constructed as a series of four fusion proteins encompassing
residues Pro480-Gly638 (CT1),
Arg639-Leu813 (CT2),
Ile801-Ala993 (CT3), and
Gly994-Arg1130 (CT4). These fusion proteins
were used in co-precipitation experiments with Hck as described in the
legend to Fig. 3.
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Fig. 3.
Hck interacts with multiple regions of
Abl. Recombinant GST-Abl fusion proteins shown in Fig. 2 (or GST
alone as negative control) were co-expressed with Hck in Sf-9 insect
cells. The fusion proteins were precipitated from clarified cell
lysates with glutathione-agarose beads, washed with RIPA buffer, and
associated Hck was visualized by immunoblotting (Bound).
Recovery of each GST fusion protein was determined by immunoblotting an
aliquot of the precipitate with anti-GST antibodies (GST).
The asterisks indicate the positions of the full-length
fusion proteins. To verify equivalent expression of Hck in each sample,
an aliquot of the lysate was also blotted with anti-Hck antibodies
(Lysate). The levels of bound Hck and GST-Abl fusion
proteins were determined by densitometry, and the relative ratios of
Hck bound to GST-Abl present are presented at the top. This experiment
was repeated three times with comparable results.
-galactosidase (-gal) as a negative control. Cells were selected in the presence of
G-418 and cytokine, and expression of Hck-KE was verified by immunoblotting (data not shown). The DAGM cell populations stably expressing Hck-KE or -gal were then re-infected with retroviruses carrying p210 Bcr-Abl, p185 Bcr-Abl, or the -gal control.
Cytokine-independent proliferation was monitored using an MTT reduction
assay, and the results are presented in Fig.
4. As expected, both p185 and p210
Bcr-Abl induced rapid cellular outgrowth in the -gal control cell
populations, consistent with previous results. However, the presence of
kinase-defective Hck dramatically suppressed DAGM cell outgrowth by
both forms of Bcr-Abl relative to the -gal control cells. No
outgrowth was observed with any of the cell populations following
superinfection with the -gal control virus, indicating that
transformation to cytokine independence is dependent upon Bcr-Abl.
These data provide the first evidence that Src kinases play an
essential role in transformation signaling downstream of Bcr/Abl.
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Fig. 4.
Kinase-defective Hck suppresses
Bcr-Abl-mediated transformation of DAGM cells to cytokine
independence. Two independent populations of DAGM cells stably
expressing kinase-defective Hck (KE-1 and KE-2) or -gal control
cells were infected with recombinant p185 or p210 retroviruses or with
a -gal retrovirus as a negative control as indicated at the top.
After incubation for 3 days in the presence of IL-3 and G-418, cells
were washed into cytokine-free medium and plated in 96-well plates
(36-48 replicate wells per condition per time point). Relative numbers
of viable cells were determined after 5 days (open bars) and
6 days (filled bars) using the MTT reduction assay described
under "Experimental Procedures." Absorbance values at 570 nm for
each well were averaged and are plotted ± S.D.
-gal control cells were
treated with IL-3 and outgrowth was measured using the MTT assay. As
shown in Fig. 5, all of the cells grew
rapidly in the presence of IL-3, suggesting that the actions of Hck-KE
are specific for Bcr-Abl and are not the result of a general
suppressive effect on cell proliferation or survival.
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Fig. 5.
Kinase-defective Hck does not affect
responsiveness of DAGM cells to IL-3. The populations of DAGM
cells stably expressing kinase-defective Hck (KE-1 and KE-2) or -gal
used in Fig. 4 were plated in 96-well plates in the presence of IL-3
(36-48 replicate wells per condition per time point). Relative numbers
of viable cells were determined at day 0 (open bars), after
2 days (gray bars), and after 4 days (black bars)
using the MTT reduction assay described under "Experimental
Procedures." Absorbance values at 570 nm for each well were averaged
and are plotted ± S.D.
-gal, wild-type Hck, or kinase-defective Hck as described
in the preceding section. These cell populations were then re-infected
with retroviruses carrying p210 Bcr-Abl or the -gal control, and
cytokine-independent proliferation was monitored using the MTT
reduction assay. As shown in Fig. 6,
wild-type Hck partially suppressed Bcr-Abl-induced conversion of DAGM
cells to cytokine independence relative to the -gal control. In
contrast, kinase-defective Hck produced a complete block in outgrowth,
consistent with the data shown in Fig. 4. All three of these cell lines
showed identical proliferative responses in the presence of IL-3 (data not shown). The partial suppressive action of wild-type Hck
overexpression suggests that activation of multiple Src family members
may contribute to survival and proliferative signaling by Bcr-Abl (see
"Discussion").
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Fig. 6.
Overexpression of wild-type Hck partially
suppresses Bcr-Abl-mediated transformation of DAGM cells to cytokine
independence. Populations of DAGM cells stably expressing
wild-type Hck (WT), kinase-defective Hck (KE), or
-gal were infected with a recombinant p210 retrovirus (right
three groups) or with a -gal retrovirus as a negative control
(left three groups). After incubation for 3 days in the
presence of IL-3 and G-418, cells were washed into cytokine-free medium
and plated in 96-well plates (4 wells per condition per time point).
Relative numbers of viable cells were determined after 2 days
(open bars), 4 days (gray bars), and 6 days
(black bars) using the MTT reduction assay described under
"Experimental Procedures." Absorbance values at 570 nm for each
well were averaged and are plotted ± S.D.
DISCUSSION
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ACKNOWLEDGEMENT
FOOTNOTES
Present address: Dept. of Pathology and Microbiology, University
of Nebraska Medical Center, Omaha, NE 68198.
ABBREVIATIONS
-gal, -galactosidase;
MTT, 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium
bromide.
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ABSTRACT
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REFERENCES
1.
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