The Dbl Homology Domain of BCR Is Not a Simple Spacer in
P210BCR-ABL of the Philadelphia Chromosome*
Yoshitora
Kin,
Guang
Li,
Masabumi
Shibuya, and
Yoshiro
Maru
From the Department of Genetics, Institute of Medical Science,
University of Tokyo, 4-6-1 Shirokanedai, Minato-ku, Tokyo 108-0071, Japan
Received for publication, June 13, 2001, and in revised form, July 18, 2001
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ABSTRACT |
The Dbl homology (DH) domain of BCR in
P210BCR-ABL (P210/WT) has been thought to have a negative effect on the
activation of BCR-ABL because P185BCR-ABL, in which this region is
physically deleted, has stronger biochemical and biological activities.
To study the role of the DH domain of BCR in the background of P210/WT, the region was replaced with homologous sequences derived from Dbl
(P210/Dbl) or CDC24 (P210/CDC24) or with irrelevant sequences from LacZ
(P210/LacZ) or luciferase (P210/Luci). Surprisingly, the abilities to
transform Rat1 cells or mouse bone marrow cells and induce growth
factor independence in interleukin 3-dependent mouse Ba/F3
cells were retained only in P210/Dbl. However, even P210/Dbl could not
achieve the wild type level of surviving potential against genotoxins
in Rat1 cells and in Ba/F3 cells. Activation of Akt correlated
with the biological changes in Rat1 cells but did not correlate with
the biological changes in Ba/F3 cells. The DH domain was not
tyrosine-phosphorylated in vitro, nor could we find any
differences in peptide mapping between in vitro
phosphorylated P210/WT and P210/Dbl. Although functions of the
DH domain remain to be discovered, we propose that the DH domain makes
positive contributions to P210BCR-ABL.
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INTRODUCTION |
The oncoprotein BCR-ABL is generated on the Philadelphia
chromosome found in two types of human leukemias, chronic myeloid leukemia (CML)1 and acute
lymphocytic leukemia (1). Clinical manifestation of CML is unique.
Massive expansion of myeloid cells of every maturation stage, which is
observed in chronic phase, is inevitably followed by an acute leukemic
phase called blast crisis. P210BCR-ABL found in CML and P185BCR-ABL in
acute lymphocytic leukemia differ in the BCR sequence that participates
in the formation of BCR-ABL (1, 2). The BCR sequence that is missing in
P185 but retained in P210 has a homology to the GDP-GTP exchanger
domain of Dbl and CDC24 and is therefore called the Dbl homology (DH)
domain (3). P185BCR-ABL has a stronger tyrosine kinase activity than P210BCR-ABL, and this correlates well with biological phenotypes (2).
P185BCR-ABL has stronger transforming potentials for Rat1 fibroblasts
and mouse bone marrow cells than P210BCR-ABL. In a transgenic animal
model, some P210BCR-ABL animals are even free of disease (4). Because
the sequence encoded by the BCR first exon plays a pivotal role in the
activation of BCR-ABL by binding to the ABL SH2 domain, it has
been suggested that the DH domain is simply an inhibitory spacer (5,
6). The difference in the transforming potential cannot explain the
clinical phenotype of CML, and functions of the DH domain in
P210BCR-ABL have been poorly understood.
Actin cytoskeleton staining experiments suggested that disruption of
F-actin was observed in a P185-equivalent form of BCR-ABL but not in
P210-expressing Rat1 cells, which implies that the DH domain plays a
role in stabilization of actin filaments (7). We could never show
GDP-GTP exchange activities associated with this region but a report
claimed that it activates CDC42, RhoA, and Rac (8, 9). If this is the
case, P210 could elicit signals via Rho family proteins. Those small
GTP-binding proteins are involved not only in the activation of
cytoskeleton but also in cell growth and gene expression (10, 11). For
example, cellular transformation by Dbl is mediated by the activation
of its substrates, Rho-like GTPases including CDC42 (12).
Transformation by BCR-ABL has been reported to be blocked by
dominant-negative Rac (13). BCR-ABL has also been documented to
preferentially activate Jun kinase to mitogen-activated protein kinase
(14). Although Ras is activated by BCR-ABL via Grb-2 and Shc, there are
Ras-dependent and -independent pathways leading to the
activation of Jun kinase, and CDC42 was shown to mediate Jun kinase
activation (15-19).
Recently, we have reported that P210BCR-ABL but not P185BCR-ABL binds
to the xeroderma pigmentosum group B protein (XPB) through the DH
domain and inactivates its DNA unwinding activity, at least in
vitro (20). Because XPB is an essential component of the basal
transcription factor TFIIH involved in DNA repair and
transcription, we have hypothesized that the blast crisis observed in
CML could be caused by a defect in DNA repair that potentially induces
genomic instability. We have also shown that XPB does not bind to other DH domain-containing proteins such as CDC24 and Dbl (21).
All of this information suggests that the DH domain of BCR may not be a
simple spacing region in P210BCR-ABL but could be of structural as well
as functional importance. To further address this issue, here we report
biochemical and biological analyses of replacement mutants of this region.
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EXPERIMENTAL PROCEDURES |
Molecular Construction--
The BCR fragment BglII
(nucleotide 1704) to BglII (nucleotide 2839) encoding the
Dbl homology domain (amino acids 413-789) was replaced with homologous
sequences in Dbl or yeast CDC24 or with irrelevant sequences of similar
length from LacZ or luciferase (21-24). Primers used for polymerase
chain reactions are 5'-GGAAGATCTGCAAGAAACACTTTGCATT-3' and
5'-GGAAGATCTTGAATAATGAGGATGATGAT-3' for CDC24 (amino acids 322-559), 5'-GGAAGATCTTCGCTCCCCGAAGTC-3' and
5'-GGAAGATCTGAAACTTATCCCGTTCT-3' for Dbl (amino acids 183-422),
5'-GGAAGATCTTTATGCCGGTGTTGGG-3' and 5'-GGAAGATCTCGAAGATGTTGGGGTGTTG-3'
for luciferase, and 5'-GAAGATCTGGTCGCTGGGGAA-3' and
5'-GAAGATCTCAGCAAGTGTATCTGCCG-3' for LacZ. Primers were designed to
create BglII sites at both ends of all fragments generated by polymerase chain reaction. Noncoding frames of the original LacZ and
luciferase sequences were integrated into the P210BCR-ABL sequence as
in-frame.
Molecular Reagents and Analyses--
Anti-BCR antibody (Ab) was
purchased from Santa Cruz Biotechnology (Santa Cruz, CA), anti-ABL Ab
was obtained from Upstate Biotechnology (Lake Placid, NY),
anti-phosphotyrosine Ab PY20 was obtained from ICN Biomedicals, and
anti-Akt and anti-phospho-Akt (Ser-473) were obtained from New England
Biolabs. Anti-Vav, Anti-Crkl, and anti-Shc Abs were obtained from
Upstate Biotechnology, anti-STAT5 and anti-Cbl Abs were obtained from
Santa Cruz Biotechnology, and anti-actin Ab was obtained from Chemicon.
Methyl methanesulfonate (MMS), cytosine arabinoside, and cisplatin were
purchased from Sigma. Western blot analysis, immunoprecipitation,
in vitro kinase assay, and peptide mapping of in
vitro phosphorylated BCR-ABL were performed as described
previously (25, 26). Quantitation of the intensity of the bands in
Western blotting was performed by using NIH Image program.
Cell and Yeast Cultures--
Tissue cultures of Rat1 cells,
Ba/F3 cells, WEHI cells, and mouse bone marrow cells were described
previously (26). Establishment of retroviruses, expression of BCR-ABLs
by retroviral gene transfer, and transformation assays for Rat1 cells
and mouse bone marrow cells were performed as described previously
(26). For stimulation by platelet-derived growth factor (Roche
Molecular Biochemicals), cells were starved for 12 h before
stimulation with 50 ng/ml platelet-derived growth factor. Migration
assays were performed by two methods. For Rat1 fibroblasts,
subconfluent cells were scraped, and cells that migrated into the
cell-free area were observed for up to 2 days. For Ba/F3 blood cells,
5 × 105 cells were plated to chemotaxicell (Kurabo)
attached to 24 wells. Cells that migrated through the membrane were
counted in 6 h. Survival experiments with 250 µM MMS
(Sigma), 10 µM cytosine arabinoside (Sigma), or 25 µM cisplatin (Sigma) were performed by treating cells for
1 h, followed by washing and refeeding cells with fresh media.
Cells were counted 24 h after treatment. The yeast two-hybrid system was performed as described previously (20).
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RESULTS |
Dissociation of Kinase Activity in Vitroand in
Vivo--
To study the functional significance of the DH domain in
P210BCR-ABL, we have undertaken a strategy to replace the region with
homologous sequences such as those in CDC24 and Dbl (21% and 21%
identity over 236 amino acids, respectively) or with nonhomologous or
irrelevant sequences from luciferase and lacZ (Fig.
1). We thought that polypeptide
sequences of approximately the same length would serve as suitable
substitutions for the DH domain of BCR without eliminating a
structurally positive contribution, if any, of this region in
P210BCR-ABL. The replaced region contains the entire DH domain, but a
part of the PH domain of BCR was also replaced with other
sequences.
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Fig. 1.
Schematic representation of the DH domain
mutants of P210BCR-ABL. In P210BCR-ABL (P210/WT), the
boundaries between the first exon-encoded sequence (BCR 1ST
exon) and the DH domain and the junctional site between BCR and
ABL are shown by arrows. The BCR first exon contains the
SH2-binding domain (SH2 BIND). The PH domain
(PH), the SH3 domain (3), the SH2 domain
(2), the tyrosine kinase domain (KD), and the
sequence encoded by the ABL last exon (LX) are shown. Two
BglII sites used for replacement of the DH domain of BCR are
also shown (see "Experimental Procedures"). Mutants include:
P210/CDC24, which was molecularly engineered with the DH domain of
CDC24, P210/Dbl, with that of Dbl, P210/Luci, with an irrelevant
sequence from luciferase, and P210/LacZ, with that from LacZ.
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The wild type and the DH domain mutants were retrovirally expressed in
Rat1 fibroblasts at a roughly equal level (Fig.
2, A and C).
Surprisingly, the wild type level of autophosphorylation and
transphosphorylation of an in vivo substrate (p62Dok) (27) were observed only in P210/Dbl, a P210/BCR-ABL mutant in which the DH
region was replaced with the sequence from Dbl (Fig. 2, B,
D, and E). Recruitment of Grb-2 (18) was found only in
the wild type (P210/WT) and P210/Dbl (data not shown). When
immunoprecipitated P210 and its mutants were subjected to an in
vitro kinase assay with enolase as a substrate, there was almost
no difference in phosphotransferase activity (Fig. 2, F and
G) as well as in autokinase activity (data not shown). As
expected, transformation of Rat1 fibroblasts correlated with the
in vivo kinase activity (Fig. 3, A and B).
Interestingly, there was a clear difference in the morphology of cells
transformed by P210/WT and P210/Dbl (Fig. 3C). Both of these
could transform mouse bone marrow cells (Table I).
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Fig. 2.
Dissociation of kinase activity in
vivo and in vitro. Total lysates
(A and B) or anti-ABL immunoprecipitates
(C and D) from Rat1 cells expressing mock (vector
alone; lane 1), P210BCR-ABL (P210/WT; lane
2), and the set of the DH domain mutants shown in Fig. 1 including
P210/CDC24 (lane 3), P210/Dbl (lane 4), P210/Luci
(lane 5), and P210/LacZ (lane 6) were subjected
to anti-BCR (A and C) and anti-phosphotyrosine
(anti pTyr) Western blotting. Densitometrically scored
intensities of signals of phosphotyrosine-containing BCR-ABLs from
D relative to those of protein amount in C were
calculated and are shown in E. Anti-ABL immunoprecipitates
shown in C were subjected to an in vitro kinase
assay in the presence of enolase. Phosphorylated enolases were run on a
gel and dried, and autoradiography is shown in F.
Phosphotransferase activities in F relative to the protein
amounts in C were calculated and are shown in
G.
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Fig. 3.
Transformation of Rat1 cells by the DH domain
mutants of P210BCR-ABL. Soft agar colony assays of the Rat1 cells
described in Fig. 2 were performed. Pictures of the colony
(A), the relative colony numbers compared with the control
P210/WT (B), and the morphology of the Rat1 cells
transformed by P210/WT and P210/Dbl (C) are shown.
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The physical deletion of the DH domain creates P185BCR-ABL, which is
more activated or autophosphorylated than P210BCR-ABL (2), and this
information strongly suggests that there may be a structure-based
essential difference between P185 and P210 in activation in
vivo and that the DH domain of BCR makes some positive
contributions to P210BCR-ABL.
Difference in Antiapoptotic Activity--
In survival experiments
using alkylating reagent MMS, even Rat1 cells expressing P210/Dbl could
not achieve the wild type level of antiapoptotic activity (Fig.
4D). When cells were starved of serum for 7 days, there was also a significant difference between Rat1 cells expressing P210/WT (percentage of survival, 25-42%) and
P210/Dbl (percentage of survival, 2.4-6.5%) in survival experiments performed independently three times. P210BCR-ABL has been shown to
activate phosphatidylinositol 3-kinase (PI3K), which is involved in
transformation as well as antiapoptosis (28). Activation of Akt, a
downstream effector of PI3K, was observed in Rat1 cells that expressed
P210/WT but not P210/Dbl (Fig. 4, A-C).
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Fig. 4.
Antiapoptotic activity against MMS correlates
with activation of Akt. Total lysates from serum-starved Rat1
cells expressing mock (lanes 1 and 2) with
(lane 2) or without (lane 1) stimulation by
platelet-derived growth factor (PDGF), P210/WT, and its
mutants (shown in Fig. 2) were subjected to anti-active Akt (p
Akt; A), anti-Akt (B), and anti-actin
(C) Western blotting. Survival rates against the alkylating
reagent MMS in Rat1 cells expressing P210/WT and P210/Dbl are shown in
D (means of three independent experiments).
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Combined with the results in Figs. 2 and 3, these data indicate that
even the homologous sequences from CDC24 or Dbl cannot fully substitute
for the DH domain of BCR in P210BCR-ABL when expressed in Rat1 cells. A
fragment of Dbl that was used for replacement (amino acids 466-832)
includes the GDP-GTP exchanger domain (amino acids 498-737) that has
been reported to show GDP dissociation activity, at least in
vitro, and the PH domain (amino acids 708-812) (9). Therefore,
the activities of P210/Dbl may represent either structurally
satisfactory substitution for the DH domain of BCR by the corresponding
Dbl sequence to activate ABL or the exchanger activity of Dbl or both.
However, the dissociation of biological and biochemical potential
between P210/WT and P210/Dbl shown in survival assays against MMS
indicates that there may be a function of BCR in the DH domain that
cannot be replaced by the Dbl sequence.
Structural Significance--
BCR-ABL has been shown to induce
growth factor independence in many cytokine-dependent
hematopoietic cells (29). Interleukin (IL)-3-dependent
mouse Ba/F3 cells were infected with retroviruses expressing
P210BCR-ABL or its mutants and were selected by G418 in the presence of
IL-3. Those populations of cells expressed BCR-ABL or its mutant
proteins in roughly equal amounts (data not shown). When those cells
were deprived of both serum and IL-3, cells expressing P210/CDC24,
P210/Luci, or P210/LacZ showed poor survival (Fig.
5A). Ninety-six-well assays in
culture medium containing serum but not IL-3 showed a high efficiency
(>90%) of outgrowth of IL-3-independent Ba/F3 cells in both P210/WT
and P210/Dbl expressers in 7-10 days. In P210/CDC24, the efficiency
was 40-50%. However, no wells were found to contain surviving Ba/F3
cells in P210/Luci and P210/LacZ, even at 4 weeks.
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Fig. 5.
Expression of the DH domain mutants in mouse
hematopoietic Ba/F3 cells. A, survival curves of Ba/F3 cells
that were infected by retroviruses expressing P210BCR-ABL and its
mutants (shown in Fig. 1), selected by G418 in the presence of IL-3,
and then deprived of both serum and IL-3. B, total lysates
from IL-3-dependent Ba/F3 cells (lane 1) and
Ba/F3 cells that showed an IL-3-independent growth after retroviral
infection (lanes 2-6) were subjected to anti-BCR
(left panel) and anti-pTyr (right panel) Western
blotting. Note that the molecular size of both P210/Luci and P210/LacZ
is altered (see Fig. 2A for comparison). C,
molecular structure of P210/Luci with a deletion containing the
replaced sequence in the DH region. Nucleotide sequences adjacent to
the junction (indicated by an arrow) are shown.
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Therefore, we attempted to obtain cell lines that survived against IL-3
starvation in P210/Luci or P210/LacZ by continuing cultures of the
whole infected and G418-selected population of Ba/F3 cells. We expected
that the surviving cells would express P210/Luci or P210/LacZ with gain
of function mutations or would have up-regulations of other genes in
IL-3 signaling independent of the mutant BCR-ABLs. Intriguingly, as
shown in Fig. 5, B and C, deletions were found in
both P210/Luci and P210/LacZ sequences in the Ba/F3 cells that survived
for 4-6 weeks. Reverse transcription-polymerase chain reaction
analyses revealed an in-frame deletion encompassing the replaced
sequence. In P210/Luci, the fusion point on the ABL side was 17 amino
acids carboxyl to the ATP-binding motif GXGXXG (Fig. 5C). A larger mutation that partially deletes the ABL
kinase domain sequence was found in P210/LacZ (Fig. 5B, left
panel). Neither immunoprecipitated P210/Luci nor
immunoprecipitated P210/LacZ was able to phosphorylate enolase in
vitro or bind to Grb-2 (data not shown). Because tyrosine
phosphorylation of STAT5 (30) appeared to take place in
IL-3-independent Ba/F3 cells expressing the mutated P210/Luci or
P210/LacZ (Fig. 6, A and
B) and because both the mutated P210/Luci and P210/LacZ were
kinase-inactive, those deletions could have occurred separately from
IL-3 independence and possibly with spontaneous activation of other
molecules capable of activating STAT5 (30). However, this strongly
suggests that integration of unrelated sequences in the context of
P210BCR-ABL cannot be maintained, again supporting the structural
significance of the DH domain of BCR in P210BCR-ABL.
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Fig. 6.
Tyrosine phosphorylation of STAT5, Shc, Vav1,
and the p85 subunit of PI3K. Anti-STAT5 (A and
B), anti-Shc (C and D), anti-Vav1
(E and F), and anti-p85 (G and
H) immunoprecipitates from the same set of Ba/F3 cells shown
in Fig. 5B were subjected to anti-STAT5 (B),
anti-Shc (D), anti-Vav1 (F), anti-p85
(H), and anti-pTyr (A, C, E, and G)
Western blotting.
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Antiapoptotic Activity against Chemicals--
Using
IL-3-independent Ba/F3 cells that express BCR-ABLs with retained
overall structures (namely P210/WT, P210/CDC24, and P210/Dbl), we
performed antiapoptosis assays against serum starvation and cytotoxic
chemicals including MMS, cytosine arabinoside, and cisplatin. The
survival rate against serum deprivation in P210/Dbl was roughly equal
to that in P210/WT (Fig. 7A).
However, neither P210/Dbl nor P210/CDC24 achieved the wild type level
of antiapoptotic activity against cytotoxic chemicals (Fig.
7B).
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Fig. 7.
Antiapoptotic activities of Ba/F3 cells
expressing the DH mutants against serum starvation and cytotoxic
agents. Ba/F3 cells shown in Fig. 5B were subjected to
survival experiments against serum starvation (A) and
cytotoxic reagents (B) including MMS, cytosine arabinoside
(AraC), and cisplatin (CIS), and the means of
three independent experiments are shown.
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The in vivo autophosphorylation activity was reduced in
P210/CDC24 (Fig. 5B), which is consistent with the results
from Rat1 cells shown in Fig. 2D. Tyrosine phosphorylation
of adaptor protein Shc (17, 19), GDP-GTP exchanger Vav1 (31), the p85
subunit of PI3K (Fig. 6, C, D, E, and F), and Cbl
(32, 33) (Fig. 8C) was
observed in P210/WT- and P210/Dbl-expressing Ba/F3 cells. Given that
tyrosine phosphorylation of p62Dok (see Fig. 2B) and Shc
(data not shown) also took place in Rat1 cells, it can safely be said
that the Dbl sequence is nearly sufficient to substitute for the DH
domain of BCR to activate BCR-ABL without grossly changing the
substrate specificity.
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Fig. 8.
Migration ability of P210/WT and the DH
mutant expressers. A, Ba/F3 cells expressing P210/WT,
P210/Dbl, or P210/CDC24 shown in Fig. 5B were plated into
transwells attached to 24 wells, and the relative amounts of cells that
passed through the membrane in 6 h are shown. B,
subconfluently growing Rat1 cells that express P210/WT, P210/Dbl, or
mock shown in Figs. 2 and 3 were scraped, and pictures of migrating
cells were taken at 0, 20, 36, and 48 h. C,
anti-phosphotyrosine (anti pTyr; lanes 1-6, top
panels), anti-Crkl (lanes 1-3, bottom left panel), and
anti-Cbl (lanes 4-6, bottom right panel) Western blotting
of anti-Crkl (lanes 1-3) and anti-Cbl (lanes
4-6) immunoprecipitates (top panels) and total cell
lysates (bottom panels) from Ba/F3 cells expressing P210/WT
(lanes 1 and 4), P210/Dbl (lanes 2 and
5), and P210/CDC24 (lanes 3 and
6).
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We consistently observed a difference between P210/WT and P210/Dbl in
sensitivity to cytotoxic agents such as MMS in the background of both
Rat1 cells and Ba/F3 cells. Because Akt appeared to be activated in
Rat1 cells expressing P210/WT but not P210/Dbl, we measured the kinase
activity of immunoprecipitated Akt. However, under conditions in which
platelet-derived growth factor could enhance the Akt activity by
2.1-fold over the baseline in IL-3-dependent Ba/F3 cells
starved of serum, the levels of Akt activity in Ba/F3 cells expressing
P210/WT and P210/Dbl were 1.8- and 2.0-fold, respectively.
Cytoskeletal Activation--
When the IL-3-independent Ba/F3 cells
expressing P210/WT, P210/Dbl, or P210/CDC24 shown in Fig. 5B
were subjected to transwell assay, there was a significant difference
between P210/WT and P210/CDC24 in the number of cells that migrated
through the membrane (Fig. 8A). P210/Dbl showed an
intermediate ability for migration. BCR-ABL has been shown to
phosphorylate Crkl and Cbl, both of which play an important role in
migration of blood cells (33, 34). Tyrosine phosphorylation of both
Crkl and Cbl was observed in Ba/F3 cells expressing P210/WT and
P210/Dbl but not P210/CDC24 (Fig. 8C), which correlates well
with the biological data in Fig. 8A. The wound healing assay
also revealed a higher migrating ability in Rat1 fibroblasts that
express P210/WT or P210/Dbl than in cells expressing mock (vector
only). Rat1 cells with P210/CDC24, P210/Luci, or P210/LacZ behaved in a
similar fashion to mock-expressing cells. This is consistent with a
recent report that claims that activation of Akt correlates with cell
migration (35).
Investigation of Mechanism--
The DH sequence from Dbl appeared
to substitute for the BCR DH sequence in the activation of P210BCR-ABL
in terms of the ability to cause both cellular transformation and
growth factor independence, but not in terms of the ability to cause
survival against genotoxic agents. The DH domain could participate in
the formation of a special molecular structure in P210BCR-ABL,
independently or in concert with another portion of the molecule. This
structure may play a role in binding to or recognizing signaling
molecules such as substrate.
One possible mechanism would be that activated BCR-ABL is unable to
autophosphorylate specific sites in the DH domain of BCR if it is
replaced by other sequences. Although there are two tyrosine residues
(BCR 561 and 598) in the DH region of `BCR that are conserved with
neither Dbl nor CDC24, tryptic peptide mapping analyses of in
vitro autophosphorylated P210/WT, P210/Dbl, and P210/CDC24 revealed almost no difference (Fig. 9).
Coexpression studies of P210BCR-ABL with a BCR mutant (23) lacking the
SH2-binding domain alone (BCR
162-413) or lacking both the
SH2-binding domain and the DH domain (BCR162-631) showed that
neither of the mutants can be tyrosine-phosphorylated (data not
shown).
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Fig. 9.
Peptide mapping of in vitro
phosphorylated P210/WT and P210/Dbl. Anti-ABL
immunoprecipitates from Rat1 cells expressing P210/WT or P210/Dbl that
were subjected to an in vitro kinase reaction as shown in
Fig. 2, F and G, were run on a gel, and bands
corresponding to autophosphorylated P210/WT (A) and P210/Dbl
(B) were cut out and subjected to tryptic peptide mapping.
Mixed samples from P210/WT and P210/Dbl were also examined
(C). Major spots designated a-l are shown.
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By utilizing the yeast two-hybrid system, we also examined the second
possibility regarding whether or not there is an interaction between
the ABL SH2 domain and the DH domain because poor activation of the
PI3K/Akt pathway has also been reported in the SH2 domain mutant (13).
Under conditions in which the SH2 domain binds to the full-length
P210BCR-ABL and the DH domain binds to XPB (20), we could observe no
interaction between the SH2 domain and the DH domain.
We have previously reported the DH domain-mediated binding of BCR, but
not of Dbl or CDC24, to XPB, suggesting that there is a specific
interaction of the DH domain with other molecules (21). With
full-length P210BCR-ABL and P185BCR-ABL as bait, yeast two-hybrid
differential screening was undertaken to search for molecules that
interact with the DH domain of BCR in the context of P210BCR-ABL. Both
tissue glutaminase and Arp2 were found to be positive in P210 bait but
negative in P185. However, we could coimmunoprecipitate neither of them
with P210 expressed in Rat1 cells or Ba/F3 cells in repeated
experiments (data not shown). In addition, coexpression of tissue
glutaminase and P210BCR-ABL did not change the autophosphorylation
activity in vivo. We could observe no difference between
P210/WT and P210/CDC24 (or P210/Dbl) in the amount of
coimmunoprecipitated actin (data not shown).
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DISCUSSION |
Abrogation of biochemical and biological functions by
replacement of the DH domain of BCR in P210BCR-ABL with that of
CDC24 or with irrelevant sequences such as LacZ or luciferase was
surprising because a naturally occurring physical deletion of the DH
domain in P210BCR-ABL is found in P185BCR-ABL, an alternative form of BCR-ABL that is more transforming than P210 (2). This seemingly contradictory evidence suggests that P185BCR-ABL and P210BCR-ABL are
distinct from each other in terms of structure-based activation status
and that the simple presence or absence of the DH domain sequence in
BCR-ABL cannot explain the activation levels. In the context of
P210BCR-ABL, this region plays an important role in activation. At
least two aspects should be noted: structural significance and
functional significance.
The occurrence of the large deletion spanning the inserted sequence in
the DH region in P210/Luci and P210/LacZ expressed in Ba/F3 cells
strongly suggests that those molecules are structurally unstable and
that P210BCR-ABL cannot maintain the structure of such irrelevant
sequences (possibly at the level of mRNA) because reverse
transcription-polymerase chain reaction analysis of Ba/F3 cells that
survived against IL-3 deprivation revealed that clones carrying an
in-frame deletion of the inserted sequence gave rise to growth.
P210/CDC24, which was stably expressed in those cells, could not exert
full biochemical and biological activities. The dramatic reduction of
tyrosine phosphorylation of BCR-ABL substrates such as Shc, Vav1, the
p85 subunit of PI3K, Crkl, and Cbl correlated well with decreased
potentials in antiapoptosis and migration in Ba/F3 cells expressing
P210/CDC24.
Protein-protein interactions are often mediated by modifications such
as phosphorylation. It has been shown that P210BCR-ABL has different
phosphorylation sites from those in P185, as judged by peptide mapping
analysis (36). The exchanger activity of the Vav1 protein that contains
the DH domain has been reported to be activated by tyrosine
phosphorylation (37). However, the site of phosphorylation does not
fall into the DH domain. Results from peptide mapping studies, yeast
two-hybrid assays, and coexpression studies of P210BCR-ABL and BCR
mutants of the DH domain suggest that the DH domain of BCR in
P210BCR-ABL does not appear to be tyrosine-phosphorylated to bind to
other molecules with the SH2 domain. The SH2 mutant in P210BCR-ABL has
a similar biochemical and biological phenotype as the DH mutants, which
suggests that those two domains might work in concert to elicit signals
from the SH2 domain. However, no interaction was found between the DH
and SH2 domains when tested by the yeast two-hybrid system.
The second aspect is the biochemical activities belonging to the DH
domain of BCR that are expected to be distinct from those in Dbl or
CDC24. Although we have not succeeded in finding the exchanger activity
when the purified BCR protein from baculovirus was subjected to
exchange assays, one group has claimed that the DH domain of BCR
functions as a GDP-GTP exchanger for CDC42, RhoA, and Rac when
expressed in Escherichia coli (8). The fragment of Dbl we
have utilized for replacement has been shown to function as an
exchanger for CDC42 in vitro (38). Therefore a part of the
biological function could be derived from the inserted Dbl sequence in
P210/Dbl. However, possible activation of CDC42 in both P210/WT and
P210/Dbl cannot explain the biological differences in survival against
genotoxins and differences in morphology of transformed Rat1 cells.
P210/CDC24 containing the exchanger domain of CDC24 from yeast may not
function toward its substrate CDC42 of mammalian origin.
Drug resistance in P210BCR-ABL-expressing cells was shown to be
mediated by protein kinase C 
(39). However, we could observe no
difference in the kinase activities of protein kinase C or protein
kinase C 
between cells expressing P210/WT and cells expressing
P210/Dbl (data not sown). We have reported previously that XPB binds to
BCR, but not to CDC24 or Dbl (21). This is an example of differential
binding of the DH domain to other molecules. P210/WT and P210/Dbl could
have a different antirepair activity and antiapoptotic activity because
XPB has been shown to bind to p53 in the apoptotic pathway (40).
Although additional experiments need to be performed, an altered
interaction of P210BCR-ABL with XPB might explain the biological differences.
| |
ACKNOWLEDGEMENTS |
We thank Dr. Richard Cerione (Cornell
University) and Dr. Y. Nojima (Gunma Medical School) for helpful discussions.
| |
FOOTNOTES |
*
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. Tel.: 03-5449-5629;
Fax: 03-5449-5425; E-mail: ymaru@ims.u-tokyo.ac.jp.
Published, JBC Papers in Press, August 13, 2001, DOI 10.1074/jbc.M105484200
| |
ABBREVIATIONS |
The abbreviations used are:
CML, chronic myeloid
leukemia;
DH, Dbl homology;
IL, interleukin;
XPB, xeroderma pigmentosum
group B protein;
Ab, antibody;
MMS, methyl methanesulfonate;
PI3K, phosphatidylinositol 3-kinase;
STAT, signal transducers and activators
of transcription. SH2, Src-homology;
TFII, class II transcription
factor;
PH, pleckstrin-homology.
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