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Molecular and Cellular Biology, February 1999, p. 1171-1181, Vol. 19, No. 2
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Biological Effects of c-Mer Receptor Tyrosine
Kinase in Hematopoietic Cells Depend on the Grb2 Binding Site in the
Receptor and Activation of NF-
B
Maria-Magdalena
Georgescu,
Kathrin H.
Kirsch,
Tomoyuki
Shishido,
Chen
Zong, and
Hidesaburo
Hanafusa*
Laboratory of Molecular Oncology, The
Rockefeller University, New York, New York 10021
Received 9 June 1998/Returned for modification 5 August
1998/Accepted 3 November 1998
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ABSTRACT |
The c-Mer receptor tyrosine kinase (RTK) is most closely related to
chicken c-Eyk and belongs to the Axl RTK subfamily. Although not
detected in normal lymphocytes, c-Mer is expressed in B- and T-cell
leukemia cell lines, suggesting an association with lymphoid malignancies. To gain an understanding of the role of this receptor in
lymphoid cells, we expressed in murine interleukin-3 (IL-3)-dependent Ba/F3 pro-B-lymphocyte cells a constitutively active receptor, CDMer,
formed from the CD8 extracellular domain and the c-Mer intracellular
domain. Cells transfected with a plasmid encoding the CDMer receptor
became IL-3 independent. When tyrosine (Y)-to-phenylalanine (F)
mutations were introduced into c-Mer, only the Y867 change significantly reduced the IL-3-independent cell proliferation. The Y867
residue in the CDMer receptor mediated the binding of Grb2, which
recruited the p85 phosphatidylinositol 3-kinase (PI 3-kinase). Despite
the difference in promotion of proliferation, both the CDMer and mutant
F867 receptors activated Erk in transfected cells. On the other hand,
we found that both transcriptional activation of NF-
B and activation
of PI 3-kinase were significantly suppressed with the F867 mutant
receptor, suggesting that the activation of antiapoptotic pathways is
the major mechanism for the observed phenotypic difference. Consistent
with this notion, apoptosis induced by IL-3 withdrawal was strongly
prevented by CDMer but not by the F867 mutant receptor.
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INTRODUCTION |
The human c-Mer receptor tyrosine
kinase (RTK) has been identified by screening a B-lymphoblastoid
expression library with antiphosphotyrosine antibodies (22),
and mouse c-Mer was described as a homologue of human c-Mer
(21). We also independently isolated c-Mer in the search for
the mammalian homologue of avian c-Eyk by screening a mouse embryo
library (50). Previously, the proto-oncogene c-eyk, which encodes the c-Eyk RTK (25), was
identified as the cellular counterpart of a sarcoma-inducing oncogene
of an avian retrovirus (26).
Both c-Mer and c-Eyk have the same overall structure, consisting of an
extracellular region comprising two immunoglobulin-like and two
fibronectin type III repeats, a transmembrane region, and an
intracellular region containing the kinase domain. This particular
structure led to their assignment to the Axl/Ufo subfamily of RTKs
(35). The amino acid sequence identity between c-Eyk and
mouse c-Mer (69% in the intracellular domain) is lower than that
between the mouse and human c-Mer proteins (86%) but higher than that
between c-Mer and other members of the Axl RTK family (e.g., 57%
identity with mouse Axl), suggesting that c-Mer might be a homologue of
c-Eyk (21). The ligand for c-Eyk is unknown, and only very
recently were data obtained indicating that Gas6 is a ligand for c-Mer
(10, 33). Gas6 has been previously identified as the ligand
for Axl (45) and Rse (18), both members of the Axl RTK family. The physiological roles of the Axl family receptors are
not known. Recently, it has been shown that Gas6-Axl signaling through
the phosphatidylinositol 3-kinase (PI 3-kinase) and Src-dependent pathways was required for the prevention of apoptosis in cells expressing this receptor (20). The signaling pathway of
c-Eyk was studied by utilizing a CD8-c-Eyk fusion system that is
constitutively activated through dimerization (49). This
study indicated that activated c-Eyk specifically stimulates the
Jak-Stat pathway, with little effect on the mitogen-activated protein
(MAP) kinase or c-Jun N-terminal kinase (JNK) pathway. Upon
constitutive activation, it also induces rat cell transformation, which
appears to be correlated with Stat activation. A study of c-Mer
signaling and transformation, using colony-stimulating factor 1 stimulation of an Fms-Mer chimeric receptor transfected into NIH 3T3
fibroblasts, pointed out that fibroblasts proliferate and can be
transformed upon stimulation (30). Although Stat activation
was not investigated, the authors showed that phospholipase C-
(PLC-), PI 3-kinase/p70 S6 kinase, Grb2, Shc, Raf-1, and MAP kinase
are downstream components of the c-Mer transduction pathways. This
suggested that c-Eyk and c-Mer signal through different downstream effectors.
The expression of the c-Mer mRNA occurs mainly in monocytes and tissues
of epithelial and reproductive origin (22). Although it is
not detected in normal peripheral lymphocytes (22) or in
thymocytes (21), c-Mer is expressed in B- and T-cell
leukemia cell lines, suggesting an association of its expression with
lymphoid malignancies (22). In this study, to gain an
understanding of the signaling of c-Mer in hematopoietic cells, we
expressed a constitutively active receptor, CDMer, formed from the
extracellular region of CD8 and the intracellular region of c-Mer, in
hematopoietic cells that do not express endogenous c-Mer. These cells,
which require interleukin-3 (IL-3) for growth, were rendered IL-3
independent when stably transfected with the CDMer receptor. To
determine which region in the c-Mer intracellular domain conveys
signals for proliferation, we altered four tyrosine (Y) residues, three of which are conserved among the members of the Axl RTK family, to
phenylalanine (F). A Y867-to-F mutation in the Grb2 binding site of the
receptor, but not other Y-to-F mutations, reduced significantly the
ability of transfected cells to proliferate in the absence of IL-3.
While looking for the pathway responsible for the difference in
proliferation, we found that nuclear factor B (NF-B) was strongly
activated in cells expressing CDMer and significantly less activated in
cells expressing the F867 mutant receptor. We show here that
constitutively active c-Mer induces NF-B activation, which is
correlated with the proliferative and antiapoptotic effects of this
receptor in hematopoietic cells.
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MATERIALS AND METHODS |
Generation of CDMer and mutant receptors.
The full-length
mouse c-Mer (994 amino acids) was cloned from a 16-day-old mouse embryo
cDNA library. The retroviral expression vector pLXSN (31),
in which the cloning site was modified by the insertion of the
EcoRI site between the XhoI and BamHI
sites, was used for cloning a chimeric receptor, CDMer (687 amino
acids), formed from the intracellular part of c-Mer (amino acids 521 to 994, inserted between the EcoRI and BamHI sites)
and the extracellular and transmembrane domains of the human CD8
receptor (amino acids 1 to 209). The CD8 component was inserted in the
XhoI site of pLXSN as a SalI digest of the vector
BSSK (a gift of A. August). Similarly, chimeric receptors containing
mutations in the intracellular region of c-Mer were obtained. A
truncated receptor, Mer
(552 amino acids), lacking the entire
carboxy-terminal region of c-Mer was obtained by inserting a stop codon
after the kinase domain. Mutations in the intracellular region of c-Mer
were introduced by PCR with primers containing the specific mutations
(23). Mutation of the ATP-binding lysine (L) 614 to
methionine (M) resulted in the kinase-negative mutant KN, and Y-to-F
changes resulted in the mutants F544, F825, F867, F924, 2F (positions
867 and 924), and 3F (positions 544, 867, and 924). All of the PCR
amplifications were performed in 30 cycles with the proof-reading
Pfu DNA polymerase (Stratagene). The nucleotide sequence of
the intracellular region for each of these constructs was determined to
ensure that the expected mutations were present and that no additional
mutations were introduced by PCR.
Cell lines and retroviral infection.
Murine IL-3-dependent
Ba/F3 cells, a pro-B-lymphocyte cell line (37), grown in
RPMI 1640 supplemented with 10% fetal calf serum (FCS) and 0.5% mouse
IL-3-containing supernatant from the IL-3-overproducing X63 derivative
cell line (27), were used for generating cell lines stably
expressing the various receptors. Bosc23 retrovirus-packaging cells
(38), maintained in Dulbecco modified Eagle's medium with
10% FCS, were transfected in duplicate, using Lipofectamine (Gibco
BRL) and 10 µg each of the plasmids encoding the various receptors.
After 30 h, the transfected Bosc23 cells were treated for 3 h
with mitomycin C (10 µg/ml) to arrest cell growth, washed three times
with phosphate-buffered saline (PBS), and subsequently cocultured for
48 h with 106 Ba/F3 cells in the presence of IL-3 and
Polybrene (4 µg/ml; Sigma). Infected Ba/F3 cells were transferred to
new culture dishes and grown in selection medium containing G418 (1 mg/ml; Calbiochem). Stably transfected Ba/F3 cells were obtained after
approximately 8 days of selection and further maintained in medium
containing 0.5 mg of G418/ml.
Cytofluorometric analysis of cells.
The levels of expression
of the stably transfected receptors were periodically determined by
cytofluorometric analysis. Two anti-CD8 primary antibodies were used,
with similar results: the monoclonal antibody OKT8 (Ortho) and the
fluorescein (FITC)-conjugated antibody 3B5 (Caltag). Cells
(106) were incubated for 30 min with the primary antibody
and then washed three times with cold PBS containing 5% FCS and 0.02%
sodium azide. When the primary antibody was directly labeled with FITC, a matching-isotype FITC-conjugated control (Caltag) was used.
Apoptosis of cells deprived of IL-3 for various periods of time (from 9 to 16 h) was measured by using FITC-conjugated annexin V
(PharMingen) (46) and propidium iodide staining as directed by the manufacturer. Fluorescence was detected with a FACScan flow
cytometer (Becton Dickinson), and 10,000 to 20,000 cells were acquired
and analyzed with the Cell-Quest software.
Proliferation assay and inhibition of growth by the use of
inhibitors.
The proliferation of cells transfected with plasmids
encoding the various receptors in the absence of IL-3 was assessed with the colorimetric CellTiter 96 aqueous nonradioactive cell proliferation assay system (Promega). Cells were washed twice in RPMI 1640 supplemented with 5% FCS, counted with a hemocytometer after treatment
with trypan blue, and dispensed in 96-well plates at a density of
2 × 104 or 1 × 105/well. Cells were
cultured in RPMI 1640 with 10% FCS either in the absence of IL-3 or
with IL-3 at optimal concentration for various periods of time. The
cells were subsequently incubated for 4 h with the tetrazolium
reagents provided in the CellTiter 96 kit in accordance with the
instructions of the manufacturer. The absorbance at 490 nm, measuring
the amount of the tetrazolium reagent
[3-(4,5)-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium inner salt (MTS) that is reduced in direct proportion to the number of
living cells, was recorded in an enzyme-linked immunosorbent assay
plate reader.
Inhibitors of different signaling pathways were used in a proliferation
assay. A proliferation dose-response curve was produced
for
IL-3-deprived, CDMer-transfected cells, using SB 203580 (Calbiochem),
which specifically inhibits the p38 MAP kinase (
12), and
wortmannin
and LY 294002 (Calbiochem), which inhibit the PI 3-kinase.
To
compare the levels of proliferation of cells expressing the various
receptors, 50% inhibitory doses were used. Wortmannin was used
in
doses of 0.8 and 1.6 µM, previously reported to inhibit the
phosphorylation of the S6 kinase that is downstream of the PI
3-kinase
but not that of the MAP kinase in Ba/F3 cells (
28).
PD
098059 (Calbiochem), which inhibits MAP kinase kinase MEK1
(
13), was used at 40 µM, the highest concentration at
which,
in our hands, the compound did not precipitate in the
medium.
Immunoprecipitation, in vitro binding assay, and
immunoblotting.
Cells were deprived of IL-3 by washing them twice
and then culturing them overnight in medium without IL-3. IL-3-deprived or nondeprived cells, washed once in cold PBS containing 1 mM sodium
orthovanadate, were lysed in lysis buffer (50 mM HEPES [pH 7.5], 150 mM NaCl, 10 mM EDTA, 10% glycerol, 1% Triton X-100, 1 mM sodium
orthovanadate, 0.1 mM sodium molybdate, 1 mM phenylmethylsulfonyl fluoride, 21 µg of aprotinin/ml 5 µg of leupeptin/ml). Proteins were immunoprecipitated by incubating the lysate with specific antibodies for 2 h or overnight and further collected on protein A/G-agarose beads (Santa Cruz Biotechnology) for 1 h at 4°C. The antibodies against c-Mer were kindly provided by H.-J. Kung
(30), and those used for immunoprecipitating p85 PI 3-kinase
were from L.-H. Wang. Other antibodies were purchased from Transduction Laboratories (anti-Grb2, anti-Shc, and antiphosphotyrosine [RC20]), Santa Cruz Biotechnology (anti-Grb2, anti-p85 PI 3-kinase, anti-Sos, anti-Erk1, and anti-Erk2), Upstate Biotechnology (antiphosphotyrosine [4G10]), and Sigma (anti-activated Erk). For in vitro association experiments, 10-µg quantities of glutathione S-transferase
(GST) fusion proteins prepared by standard procedures were incubated with 3-mg quantities of cell lysates, and the complexes were collected by using glutathione-agarose beads (Molecular Probes). The immune complexes were washed three times in lysis buffer, denatured by boiling
for 10 min in double-strength sample buffer (0.125 M Tris-HCl [pH
6.8], 4% sodium dodecyl sulfate (SDS), 10% 2-mercaptoethanol, 20%
glycerol, 0.004% bromophenol blue), and resolved by SDS-polyacrylamide gel electrophoresis (PAGE). Proteins were transferred onto Immobilon membranes (Millipore). The membranes were blocked with 3% bovine serum
albumin (Sigma) in TBS-T buffer (10 mM Tris-HCl [pH 8], 150 mM NaCl,
0.1% Tween 20) overnight at 4°C and then probed with specific
antibodies. After incubation with specific horseradish peroxidase-conjugated secondary antibodies (Jackson ImmunoResearch Laboratories), the complexes were visualized with enhanced
chemiluminescence solutions (NEN).
MAP kinase assay.
Cells deprived of IL-3 overnight were
stimulated with 0.5% IL-3 for 10 min. Stimulated and unstimulated
cells were lysed in kinase lysis buffer (10 mM Tris-HCl [pH 7.5], 50 mM NaCl, 30 mM sodium pyrophosphate, 50 mM sodium fluoride, 20 mM
-glycerophosphate, 1 mM EDTA, 1 mM EGTA, 1% Triton X-100), and Erk1
and -2 were immunoprecipitated from the lysates. In vitro kinase
reactions were carried out in 20-µl volumes of kinase reaction buffer
containing 30 mM HEPES [pH 7.1], 10 mM MgCl2, 1 mM
dithiothreitol, 50 µM ATP, 2.5 µCi of [-32P]ATP,
and 1 µg of myelin basic protein (Sigma) as substrate. Following
incubation for 30 min at 30°C, the reactions were terminated by
addition of 5× sample buffer and proteins were resolved by SDS-PAGE.
Luciferase assays.
Transfection of Ba/F3 cells (2.5 × 106) with 10-µg quantities of the different luciferase
reporter plasmids was done by electroporation at 960 µF and 300 V in
culture medium at room temperature. After 12 h of recovery in
IL-3-containing complete medium, the cells were washed twice,
resuspended in RPMI supplemented with only 0.5% FCS, and divided into
two portions; half of the cells were starved for 12 h, and half
were starved for 6 h and subsequently stimulated with IL-3 for an
additional 6 h. Cytoplasmic extracts and luciferase assays were
performed in accordance with the Promega protocol. The
NF-B-luciferase reporter construct contains four repeats of the
NF-B-responsive element in a Rous sarcoma virus long terminal repeat
minimal promoter (41) cloned in the vector pGV-B2 (Toyo Ink)
(1). The minimal promoter lacking the NF-B repeats was
also engineered in the pGV-B2 luciferase reporter vector. The
inhibition of the NF-B activity was assayed by cotransfecting 10 µg of the inhibitor of B (IB-), cloned in the vector pRc/CMV (24), and 7 µg of the NF-B reporter plasmid into Ba/F3 cells.
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RESULTS |
Expression of CDMer and mutant receptors in IL-3-dependent
cells.
To dissect the signal transduction pathway of the c-Mer
tyrosine kinase receptor, Y-to-F mutations were engineered in a
constitutively active chimeric molecule, CDMer, formed from the
extracellular domain of CD8 and the intracellular domain of the
mouse c-Mer receptor. The extracellular domain of CD8 induces
ligand-independent dimerization and, hence, constitutive activation of
the dimeric receptor by forming intermolecular disulfide bonds
(49). The intracellular part of c-Mer contains 16 tyrosine
residues: 13 in the kinase domain, 1 in the N-terminal region, and 2 highly conserved residues among the members of the Axl RTK subfamily in
the C-terminal region (Fig. 1A). One
tyrosine in the kinase domain that is part of the consensus binding
motif for the p85 PI 3-kinase (42) and all three tyrosines
from the extrakinase regions were mutated, resulting in the single
mutants F544, F825, F867, and F924 and the double and the triple
mutants 2F and 3F, respectively (Fig. 1A). A deletion of the C-terminal
part of c-Mer resulted in the Mer truncated receptor. The
kinase-negative receptor KN was obtained via a K614-to-M mutation in
the kinase ATP-binding site.
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FIG. 1.
Expression of CDMer and mutant receptors. (A) Schematic
drawing of c-Mer and the chimeric receptors used in this study. The
transmembrane (TM) and extracellular regions of c-Mer, the latter
consisting of two immunoglobulin-like (IG1 and IG2) and two fibronectin
type III (FN1 and FN2) repeats, are replaced by the extracellular and
transmembrane regions of CD8 in the CDMer construct. The intracellular
region of c-Mer is schematically divided into the kinase domain,
flanked by N-terminal (N-term) and C-terminal (C-term) domains. The
amino acids that were mutagenized in the intracellular region of c-Mer
and their corresponding 4-residue motifs are indicated above the map of
c-Mer. Amino acid positions correspond to the c-Mer sequence. (B)
Expression and phosphorylation of CDMer and mutant receptors. Receptors
were immunoprecipitated (IP) with anti-CD8 antibodies from lysates of
stably transfected Ba/F3 cells and detected as doublets of 91 to 93 kDa. Filters were Western blotted (WB) with antiphosphotyrosine
antibody (pY), stripped, and reprobed with anti-Mer antibody. Due to
the constitutive dimerization mediated by the CD8 extracellular
regions, the receptors autophosphorylate in the absence of ligand. Data
for only one transfected cell population for each receptor are shown,
and they are identical to those for a second, independently transfected
population.
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In the IL-3-dependent Ba/F3 cells, we did not detect endogenous
expression of c-Mer by immunoblotting with anti-Mer antibody
or by
reverse transcription of extracted mRNA followed by PCR
with specific
primers (data not shown). In these cells, CDMer
and mutant receptors
were expressed at similar levels, as determined
by immunoblotting
following immunoprecipitation with an anti-CD8
specific antibody (Fig.
1B) or by fluorescence-activated cell
sorter (FACS) analysis, except
for the Mer
receptor, which by
FACS analysis had a lower expression
level (data not shown). The
receptors, immunoprecipitated with anti-CD8
antibody, migrated
in SDS-PAGE gels as doublets of 91 to 93 kDa (Fig.
1B). The Mer
truncated receptor had a lower molecular mass. We
examined the
phosphorylation of the mutant receptors by immunoblotting
with
an antiphosphotyrosine antibody and found that all of the
receptors
were similarly phosphorylated (Fig.
1B). This indicated that
the
substituted tyrosines neither impaired the c-Mer kinase's ability
to autophosphorylate nor were major sites of autophosphorylation.
As
expected, the KN receptor did not show
autophosphorylation.
The kinase activity and Y867 residue of CDMer are required to
induce IL-3-independent cell proliferation.
We analyzed the
ability of Ba/F3 cells stably expressing CDMer or mutant receptors to
proliferate in the absence of IL-3. Cells were plated in equal numbers
in medium lacking IL-3, and their growth after 48 or 72 h was
compared to that of matched cells grown in the presence of IL-3. As
shown in Fig. 2, the cells expressing
CDMer or one of three single mutants, F544, F825, or F924, maintained
IL-3-independent growth. In contrast, IL-3-deprived cells transfected
with the vector alone or with plasmids encoding the KN or Mer
receptor exhibited minimal growth. Cells expressing the single-mutant
F867, the double-mutant 2F, or the triple-mutant 3F receptor (the last
two containing a mutation at Y867) displayed an intermediate phenotype
in the proliferation assay. These data indicated that the
constitutively active CDMer receptor could substitute signaling through
the IL-3 receptor for cell proliferation and that Y867 is the major
site for mediating this effect. The other mutation in the carboxyl tail
(position 924) did not appear to impair cell growth, as shown for the
single and double mutants. Cells with the triple-mutant receptor 3F,
containing Y-to-F changes at all of the tyrosines of the extrakinase
regions, exhibited a more profound retardation of growth than did those
with the F867 receptor. Interestingly, the mutation at Y825, which lies in a PI 3-kinase consensus binding motif, promoted an increased proliferation of the cells. Cell proliferation was observed with all of
the Y-to-F mutants, implying that other tyrosines in the kinase region
or the presence of the tyrosine kinase activity of c-Mer might account
for a basal proliferation level in cells deprived of IL-3.
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FIG. 2.
Proliferation of cells expressing CDMer and mutant
receptors. Cells were seeded in equal initial numbers
(105/well) for five replicates of each transfected cell
population in medium with and without IL-3. After 48 or 72 h, the
absorbance at 490 nm, corresponding to the capacity of living cells to
reduce MTS (tetrazolium reagent), of each culture was measured. Columns
represent the percentage ratio of the mean absorbance of cells grown
without IL-3 to the mean absorbance of the same cells grown in the
presence of IL-3, and they reflect the ability of cells to grow in the
absence of IL-3. Standard deviations, indicated by the error bars, were
calculated from the percentage values obtained for two independently
transfected populations of each construct. This experiment was repeated
four times with similar results.
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We next examined whether these cells could be maintained in culture in
the absence of IL-3 for longer periods of time. Cells
transfected with
the vector or with the plasmid encoding the KN
receptor mutant died
after 3 days of incubation in medium lacking
IL-3. This confirmed that
the kinase activity was required for
the proliferation phenotype.
Consistent with their behavior after
3 days in the proliferation assay,
CDMer, F544, F825, or F924
receptor-expressing cells did not die and
could be propagated
in the absence of IL-3. After 2 weeks of culture in
medium without
IL-3, these cells showed only a slight increase in the
expression
level of the receptor compared to cells cultured in medium
containing
IL-3 (Fig.
3). In the absence
of IL-3, the majority of the cells
expressing the Mer
truncated-receptor mutant or, to a lesser
extent, the cells expressing
receptors with a mutation at Y867
died in the first 4 to 5 days of
culture. However, after 7 days,
cells growing independently of IL-3
could be selected. These selected
surviving cells had significantly
increased receptor expression
levels compared to the corresponding
control cells grown in the
presence of IL-3 (Fig.
3). This experiment
showed that the receptors
containing nonmutated Y867 residues were able
to sustain long-term
IL-3-independent proliferation. The need for a
large increase
in the level of expression of receptors with a mutation
at Y867
in order to maintain proliferation suggested that Y867 is a
major
determinant in the proliferation process.
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FIG. 3.
Increased receptor expression after selection of cells
in the absence of IL-3. Cells expressing the indicated receptors were
maintained for 14 days in medium with (+) IL-3 (control cells)
(filled-in curve) or without ( ) IL-3 (selected surviving cells)
(unfilled curve). The expression of the receptors was detected by
FACScan analysis using an FITC-conjugated anti-CD8 antibody. A scheme
of the selection process is shown above the receptor expression
histograms.
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The Y867 residue in the receptor mediates the binding of Grb2 and
the recruitment of p85 PI 3-kinase complexed to a phosphorylated p95
protein.
Y867 is part of a Grb2 consensus binding motif
(42). While receptors without a mutation at this site
coimmunoprecipitated with Grb2, the Y867-to-F mutants lost the ability
to bind Grb2 (Fig. 4A). The amount of
Grb2 bound to the receptor was very low, less than 0.2% of the total
Grb2 present in the lysate. We could not show direct binding of c-Mer
to other endogenously expressed molecules, such as PLC-, the p85
subunit of PI 3-kinase, or protein tyrosine phosphatase 1C or 1D, in
coprecipitation assays (data not shown).
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FIG. 4.
Binding of Grb2 to the receptor and recruitment of p85
PI 3-kinase are dependent on Y867. (A) Binding of Grb2 to the receptors
requires phosphorylation of Y867 in the Grb-2 consensus motif. Filters
containing immunoprecipitates (IP), obtained with the indicated
antibodies, of 3-mg portions of protein from lysates of IL-3-starved
cells were Western blotted (WB) with the indicated antibodies. (B) Grb2
complex formation. Protein (3 mg) from lysates of IL-3-starved cells
transfected with pLXSN vector or with a plasmid encoding CDMer or the
F867 mutant receptor were incubated with GST-Grb2 fusion proteins. GST
was fused to full-length (FL) Grb2 or to either of two Grb2 domains:
the SH2 domain and the C-terminal SH3 domain (C-SH3). GST alone was
used as a control. The filter was probed with antiphosphotyrosine
antibody (pY), stripped, and reprobed with the indicated antibodies
(WB). Immunoprecipitation of a 95-kDa phosphorylated protein (p95) with
anti-p85 PI 3-kinase antibody (C) or with GST-p85 fusion proteins
(prepared as for the GST-Grb2 fusion proteins) (D). This phosphorylated
protein associated with p85 only in cells expressing receptors with
Y867 in the Grb2 binding site.
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Grb2 contains one SH2 domain flanked by two SH3 domains and functions
as an adapter protein, coupling an activated receptor
to many other
signaling proteins (
40). To determine which proteins
associate with Grb2, we used GST-Grb2 fusion proteins in a pulldown
assay (Fig.
4B). The p85 subunit of PI 3-kinase was specifically
present in a complex with full-length Grb2 or with the C-terminal
SH3
domain of Grb2 in CDMer lysates and not in the vector- or
F867
mutant-transfected cell lysates. On the other hand, the Ras
guanine
nucleotide exchange factor Sos was associated with full-length
Grb2 in
all tested lysates. Considerably more tyrosine-phosphorylated
proteins
were associated with the GST-Grb2 fusion proteins in
the CDMer cell
lysate than in the F867 lysate (Fig.
4B).
In Ba/F3 cells, a protein of 95 kDa has been described to be tyrosine
phosphorylated and associated with p85 PI 3-kinase after
IL-3
stimulation (
32), data that we also confirmed (not shown).
We also detected phosphorylation of the p95 protein and its association
with the p85 subunit of PI 3-kinase in cells expressing CDMer
but not
in cells expressing with the plasmid encoding the F867
mutant receptor
(Fig.
4C). This association was mediated by the
N-terminal SH2 domain
of p85 PI 3-kinase (Fig.
4D). We failed
to identify this p85-binding
protein by immunoblotting with specific
antibodies to 90- to 95-kDa
proteins (CDMer, 80K-H, Gab1, FRS2,
eps8, or Stat5). A 95-kDa
phosphorylated protein was immunoprecipitated
by the C-terminal SH3
domain of Grb2 in the CDMer cell lysate
(Fig.
4B), and it is likely
that it corresponds to the p95 protein
binding to the PI 3-kinase (Fig.
4C and D). If this holds true,
the p95 protein might be an adapter
protein, bridging the binding
of PI 3-kinase to Grb2 in CDMer cells.
Similar to the p95 protein,
a not-yet-identified 97-kDa adapter protein
described in a recent
report (
17) was phosphorylated upon
IL-2 treatment of T lymphocytes
and associated with p85 PI 3-kinase
through SH2 domains and with
Grb2 through SH3 domains. Very recently, a
p95 protein phosphorylated
after stimulation with IL-3 in Ba/F3 cells
and constitutively
bound to Grb2 was identified as an adapter PH
domain-containing
molecule (
33a), and it would be
interesting to confirm that it
corresponds to the p95 protein
phosphorylated in CDMer cells.
Taken together, these data suggest that
Y867 is necessary for
binding of Grb2 to the receptor and for the
tyrosine phosphorylation
of another protein, p95, that may be required
to bring p85 PI
3-kinase into the
complex.
The MAP kinase is activated in cells expressing either CDMer or the
F867 mutant receptor, but PI 3-kinase is preferentially activated by
CDMer.
We examined whether the difference in proliferation between
the cells expressing CDMer and those expressing the F867 mutant receptor was a consequence of a defect in the activation of a signaling
pathway by the mutant receptor. In Ba/F3 cells, IL-3 activates the MAP
kinase pathway (44). To determine whether Erk is activated
by c-Mer, a MAP kinase assay was performed with cells that were IL-3
starved for 12 h. There was an approximately fivefold activation
of Erk in cells expressing CDMer or mutant receptors compared to
control vector-transfected cells (Fig.
5A). This slight activation was also
confirmed by immunoblotting of immunoprecipitated Erk with antibodies
specific for the activated Erk (Fig. 5B). The lack of a significant
difference in Erk activation between CDMer- and F867 mutant
receptor-expressing cells suggested that CDMer might activate Erk by
mechanisms independent of Y867.
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FIG. 5.
MAP kinase activation. (A) MAP kinase assay. Proteins
(400 µg) from lysates of transfected cells deprived of IL-3 for
12 h were immunoprecipitated with anti-Erk1 and anti-Erk2
antibodies and assayed for kinase activity, using myelin basic protein
(MBP) as the substrate. As a positive control, 12-h IL-3-starved cells
were stimulated for 10 min with IL-3 and assayed for kinase activity.
The amounts of immunoprecipitated Erk1 and Erk2, shown below, were
determined by subjecting the same filter to Western blotting (WB) with
anti-Erk antibodies. (B) Phosphorylation of MAP kinase. Protein (1,300 µg) from lysates prepared as described for panel A were
immunoprecipitated with anti-Erk1 and anti-Erk2 antibodies.
Immunoprecipitates were resolved by SDS-PAGE and analyzed by Western
blotting with antibodies specifically recognizing activated
phosphorylated Erk.
|
|
To assess the contribution of signaling pathways to the CDMer-dependent
cell proliferation, inhibitors blocking the PI 3-kinase
(wortmannin and
LY 294002), MEK1 (PD 098059), or p38/MAP kinase
(SB 203580) were used
in a proliferation assay at approximately
50% inhibitory doses
(dose-dependent proliferation curves are
displayed in Fig.
6A). The proliferation of
CDMer-expressing cells
was affected by all inhibitors, suggesting that
all of these pathways
contribute to the proliferation effect induced by
this receptor
(Fig.
6B). The Erk pathway inhibitor PD 098059 had a
stronger
antiproliferative effect on F867 mutant receptor-expressing
cells
than on CDMer-expressing cells, although Erk was slightly less
activated in the former (Fig.
5A). This suggested that the F867
mutant
cells deprived of IL-3 were more sensitive to inhibitory
stimuli than
CDMer-expressing cells. This increased susceptibility
to inhibition
could be explained by the impaired viability of
IL-3-deprived F867
mutant cells (Fig.
6B, upper histogram). In
contrast to the MAP kinase
inhibitors, which affected the proliferation
of F867 mutant cells more
strongly than they affected that of
CDMer-expressing cells, the PI
3-kinase inhibitors affected both
cell types to the same extent (Fig.
6B). This suggests that the
contribution of the PI 3-kinase to
proliferation is significantly
smaller in the case of F867 mutant cells
than it is in CDMer-expressing
cells.
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FIG. 6.
Proliferation of CDMer- or F867 mutant
receptor-expressing cells in the presence of inhibitors. (A)
Dose-dependent curves at 48 h for CDMer-expressing cells grown in
the presence (+IL3) or in the absence (IL3) of IL-3. (B) Cells
expressing the CDMer or F867 mutant receptor were grown in the absence
of IL-3, and vector-transfected cells, used as a control, were grown in
the presence of IL-3 (pLXSN+IL3) in a 48-h proliferation assay
(105 cells/well). The reference proliferation levels of
these cells in the absence of inhibitors (with the vehicle dimethyl
sulfoxide) are indicated by the absorbance values shown in the
upper-right miniature histogram. Wortmannin (WM), LY 294002, PD 098059, and SB 203580 were used at the indicated concentrations. The columns
represent the percentage ratio of the mean absorbance (from four
replicates) of cells treated with inhibitor to that of cells grown
without inhibitor. Error bars indicate the standard deviations of the
ratio of the two means calculated from four replicates each. This
experiment was repeated three times with similar results.
|
|
CDMer and F867 receptors induce differential NF-B transcription
activation and protection from apoptosis in the absence of IL-3.
Since the use of chemical inhibitors could not clearly distinguish
between the proliferative responses of cells expressing the CDMer and
F867 receptors, we next examined the activation of transcription
factors by using Ba/F3 cells transfected with reporter plasmids
containing specific responsive elements. Of the four promoters
tested
serum-responsive element, NF-B (1), Lyd9E for
Stat1 (47), and -casein for Stat5 (32)only
the assay for the NF-B transcription factor resulted in significant differences. As shown in Fig.
7A, the NF-B
transcriptional activity in CDMer-expressing cells was at least 10-fold
higher than that in vector-transfected cells and more than 3-fold
higher than that in cells expressing the F867 mutant receptor. This
difference correlates well with the proliferation phenotypes of these
cells, suggesting that NF-B might be an essential mediator for the
biological effects induced by c-Mer. Cells with a high level of
expression of the receptor, such as the CDMer-IL3 or F867-IL3
receptor-expressing cells selected in the absence of IL-3 (Fig. 3),
demonstrated higher levels of NF-B activation (Fig. 7B). The
specificity of NF-B activation was shown by transfecting IB-
(24), which reduced the NF-B transcriptional activity by
at least 10-fold in all of the cell lines tested (Fig. 7B). Also, the
reporter plasmid pGV-B2, containing only the minimal promoter lacking
the NF-B elements, was not activated in CDMer-expressing cells (Fig.
7B). We also analyzed whether the inhibitors used for the proliferation study affected NF-B activation (Fig. 7C). Wortmannin and LY 294002, but not SB 203580, partially decreased the activation of NF-B by
CDMer, suggesting that there might be a link between the activation of
PI 3-kinase and NF-B.
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FIG. 7.
NF-B transcriptional activation by CDMer and
F867 receptors. (A) Activation of NF-B is dependent on Y867. Cells
in equal numbers were transfected with 10 µg of NF-B-luciferase
reporter plasmid by electroporation, allowed to recover for 12 h
in complete culture medium, and divided into two portions; the
luciferase activity was measured after 12 h of IL-3 and serum
starvation (black columns) or 6 h of starvation followed by 6 h of 1% IL-3 stimulation (hatched columns). This experiment was
repeated five times with the two different transfected populations for
each construct, with similar results being obtained every time. (B)
Inhibition of NF-B activation by IB-. Cells cotransfected with
10 µg of IB- or vector (v) alone and with 7 µg of
NF-B-luciferase reporter plasmid were grown for 18 h in
complete medium, and the luciferase activities were measured after
6 h of serum and IL-3 starvation. As a control, the luciferase
reporter plasmid pGV-B2 with the minimal promoter (MP) lacking the
NF-B-responsive elements was included. Two populations of cells,
CDMer-IL3 and F867-IL3, that were selected after 2 weeks of growth in
the absence of IL-3 (see Fig. 3, in which the unfilled curves indicate
the level of receptor expression for these cells) were also tested for
NF-B transcriptional activation. This experiment was repeated twice
with similar results. (C) NF-B activation in the presence of
inhibitors. CDMer cells transfected with 10 µg of NF-B-luciferase
reporter plasmid and grown for 18 h in complete medium were
divided into three portions and either treated with wortmannin (WM),
LY294002, or SB 203580 for 6 h in medium without serum and IL-3 or
left untreated. This experiment was repeated at least twice. For
wortmannin, concentrations of 0.1, 0.5, 1, and 2 µM were tested with
similar results. For all experiments, columns represent means from
three independently transfected replicates and error bars represent the
standard deviations of these values.
|
|
Since NF-
B activation has been shown to be linked to the regulation
of programmed cell death in response to diverse stimuli
(
3),
we examined apoptosis by labeling Ba/F3 cells with annexin
V after IL-3
deprivation. By this method, early apoptotic cells
are detected since
annexin V binds to phosphatidylserine phospkolipids
that are exposed on
the external plasma membrane in an early apoptotic
stage. All
IL-3-deprived cells, whether transfected with a plasmid
encoding CDMer
or the F867 mutant receptor or with the vector
alone, exhibited
apoptosis compared with controls grown in IL-3
(Fig.
8). The number of cells undergoing early
apoptosis within
the CDMer-expressing population upon withdrawal of
IL-3 was almost
three times lower than that in the vector-transfected
population.
This indicates that CDMer protected cells from apoptosis,
although
not completely, at the given level of expression. Higher
levels
of CDMer expression completely prevented apoptosis, as observed
for CDMer-IL3 cells (Fig.
8). Cells expressing the F867 mutant
receptor
had low antiapoptotic activity, but the F867-IL3 cells
selected in the
absence of IL-3 with a very high receptor expression
level exhibited
only residual apoptosis. These data correlated
well with the levels of
NF-
B transcriptional activity in these
cells (shown in Fig.
7),
suggesting that the activation of NF-
B
might be essential for the
survival of transfected cells deprived
of IL-3.
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|
FIG. 8.
Expression of CDMer protects cells from apoptosis
induced by IL-3 withdrawal. Cells (2 × 106)
transfected with vector (pLXSN) or with a plasmid encoding the CDMer or
F867 mutant receptor were grown in medium with (+) or without () IL-3
for 12 h before being labeled with annexin V-FITC and propidium
iodide. The CDMer-IL3 and F867-IL3 cells that were selected for 2 weeks
in the absence of IL-3 (see Fig. 3, in which the unfilled curves
indicate the level of receptor expression for these cells) were grown
without IL-3. Numbers in the lower-right quadrants indicate percentages
of early apoptotic cells labeled only with annexin V.
|
|
| |
DISCUSSION |
To date, the Axl RTK family comprises three members expressed in a
wide variety of tissues (11). Unlike other RTKs, the roles
of these receptors and of their ligands are largely unknown. Axl, the
prototype member of the family, was shown to be activated by Gas6
(45). However, Gas6 was also shown to activate Rse
(18) and, more recently, c-Mer (10). Upon
stimulation with Gas6, Axl triggers antiapoptotic signals, and only
high doses of ligand induce mitogenesis (5, 19). Although
not much is known about its function in normal tissues, Axl has been
reported to be overexpressed in some malignancies (9, 43).
Based on sequence similarity, c-Mer is thought to be the mammalian
homologue of chicken c-Eyk, which was discovered as the cellular
counterpart of a retrovirus oncogene (25, 26). In our study,
we chose to express c-Mer and study its role in early lymphoid Ba/F3
cells, since c-Mer is frequently expressed in lymphoid malignant cells
(22). A constitutively active chimeric receptor containing
the intracellular domain of c-Mer was able to support IL-3-independent
growth of factor-dependent Ba/F3 cells. By mutational analysis of the
c-Mer RTK, we were able to show that the mutation of Y867 in the
carboxy terminus drastically affected the signaling and the phenotype of the cells, although other sites might also contribute to the activity of this receptor. Y867 is part of a Grb2 consensus binding site, YXNX (42), and its equivalent in the Axl receptor has also been studied in vivo and in vitro (8, 16). However, unlike c-Mer, this site in Axl is YXNM, which forms the consensus binding motif for Grb2 as well as for p85 PI 3-kinase. Thus, Axl was
shown to bind directly to Grb2 and p85 through this site (8, 16), but it was also shown by overexpression experiments to bind
to PLC-, c-Src, and Lck (8). We were not able to
demonstrate direct binding of endogenous p85 to CDMer, but we could
specifically detect it in complexes with Grb2 and a phosphorylated p95
molecule only in cells expressing CDMer and not in those expressing the F867 mutant receptor, suggesting an alternate pathway for activation of
the PI 3-kinase. Moreover, it may be an important general mechanism of
PI-3 kinase activation, since a methionine-to-alanine mutation in the
+3 position of the consensus sequence in Axl did not affect the
biological behavior induced by the receptor, although it did abolish
the direct binding of p85 to the receptor (16). Similarly to
our data, in which the Y-to-F point mutation of this site significantly reduced the proliferation and survival of the IL-3-deprived cells, deletion of the entire site in Axl extinguished the proliferation of
another IL-3-dependent cell line (16). Therefore, it appears that although they are not identical, these equivalent sites play similar and essential roles in receptor signaling.
Overall, in IL-3-dependent cells, the constitutively active c-Mer
receptor maintained growth in the absence of IL-3 by activating many
signaling pathways (Fig. 9). Some of
these, such as the MAP kinase and the PI 3-kinase pathways, were
activated by both CDMer and IL-3, as illustrated in the proliferation
assay using inhibitors. Others, like the Jak-Stat pathway or the one(s)
leading to NF-B activation, were more restricted to IL-3
(2) or CDMer signaling, respectively. Although the Jak-Stat
pathway has been shown to be activated by c-Eyk, the chicken homologue
of c-Mer (49), we did not find evidence of phosphorylation
of Jak2 and Stat5 or activation of Stat5 in CDMer-expressing cells
(data not shown). This discrepancy most likely arises from the low
degree of amino acid identity between the two receptors in their
carboxy termini (22%) and from the presence of three additional
tyrosines in the intracellular extrakinase regions of c-Eyk that might
be responsible for differences in signaling between these receptors. It
is surprising that the two chicken receptors from the Axl family
described to date, c-Eyk and Rek (7), have low degrees of
overall amino acid identity with their putative mammalian homologues,
c-Mer (56%) and Rse (68%), respectively, and that both are most
highly divergent in the carboxy terminus. Therefore, it is still
debatable whether they are orthologues of the mammalian receptors.
According to the biological data obtained with CDMer and derivative
receptors in Ba/F3 cells, the signals triggered by CDMer protected the
cells from apoptosis and induced their proliferation. The antiapoptotic
effect appeared to be mediated through the phosphotyrosine in the Grb2
binding site of the receptor, since its mutation to phenylalanine
increased the number of cells undergoing apoptosis in the absence of
IL-3 almost to the level of the vector-transfected cells. On the other
hand, in the presence of the F867 mutant receptor, the proliferation of
cells, although significantly affected, was not abolished. There
remained a basal level of proliferation, apparently independent of
Grb-2 binding, which was affected by the MAP kinase (Erk and p38)
inhibitors. This is in agreement with the presence of Erk activity in
the F867 mutant cells. It is not clear what signaling intermediates
determine this Erk activation in F867 mutant cells, since the
interaction of Grb2 with the mutated receptor is disrupted. In Ba/F3
cells, it has been shown that low levels of Ras activation are
sufficient for Erk2 activation and that these levels can be achieved by
a truncated granulocyte colony-stimulating factor receptor lacking all
intracytoplasmic tyrosines (39). In our case, an intact
kinase activity of the constitutively active CDMer and mutant receptors
that was responsible for an increased total protein phosphorylation in
cells (data not shown), together with intermolecular interactions at
other sites, might mediate the activation of the Ras-MAP kinase
pathway. Supporting this hypothesis, cells expressing the KN mutant
receptor lacked total protein phosphorylation and Erk activation (data not shown) as well as a proliferative response.
As mentioned elsewhere, Axl transmits antiapoptotic signals upon Gas6
stimulation in mouse fibroblasts, and PI 3-kinase and c-Src were shown
to be necessary in this process (20). We have shown here
that constitutively active c-Mer protects hematopoietic cells from
apoptotic death and activates NF-B in these cells. NF-B has been
shown previously to be involved in protecting cells, including B
lymphocytes, from apoptosis (4, 29, 48). In Ba/F3 cells, the
NF-B transcriptional activity was preferentially induced by the
activated c-Mer receptor and, in perfect correlation with the
antiapoptotic effect, was dependent on the tyrosine in the Grb-2
binding site of the receptor. NF-B activation can be induced by a
multitude of stimuli, including growth factors (6, 34, 36).
It would be interesting to evaluate whether Gas6 induces NF-B
activation in cells expressing receptors from the Axl family. We are
presently studying whether the activation of NF-B by c-Mer occurs
also in other cell types and, in addition, whether it is a common
denominator for the antiapoptotic effects of other members of the Axl
family. Preliminary data in studies using NIH 3T3 fibroblasts indicated
that both constitutively active c-Mer and c-Eyk activate NF-B.
The signaling events linking the c-Mer receptor to NF-B activation
are also under investigation. Mutation of the tyrosine at position 867 in c-Mer significantly decreased NF-B activation, although it did
not completely eliminate it. We have shown that this mutation disrupts
the interaction of the receptor with Grb2, but similarly to the Axl
receptor, in which this site is docking many other proteins
(8), other interactions might have also been impaired for
the F867 mutant receptor, although we were unable to detect them. Thus,
we cannot infer from the mutational study alone that Grb2, and not
another putative interactor, is required for NF-B activation. In the
preliminary study using inhibitors, the inactivation of the PI 3-kinase
appeared to decrease to some extent the activation of NF-B by CDMer.
Since both PI 3-kinase and NF-B have antiapoptotic effects, it would
be interesting to define the downstream effectors of the PI 3-kinase
pathway that contribute to the activation of NF-B. No inhibition of
CDMer-induced NF-B activity resulted from treatment with the p38
inhibitor, eliminating a role for p38 in this process. The involvement
of Erk in NF-B activation is unlikely, since Erk was activated by the F867 receptor, which itself did not significantly activate NF-B.
However, a potential role remains for Ras and Raf1, which were
previously implicated in NF-B activation (14, 15).
In summary, we have shown that the activated c-Mer RTK triggers both
antiapoptotic and proliferative signals in hematopoietic cells and that
it specifically induces the transcriptional activation of NF-B
through a tyrosine residue (position 867) in the carboxy-terminal region of the receptor. These effects confer a growth advantage to
hematopoietic cells expressing c-Mer, providing a clue to its observed
expression in lymphoid malignancies.
| |
ACKNOWLEDGMENTS |
We are very grateful to Avery August, Hajime Karasuyama,
Hsing-Jien Kung, Lu-Hai Wang, Shinya Tanaka, Klaus Okkenhaug, Lewis Cantley, Tsuyoshi Akagi, and Jean-Francois Peyron for kind gifts of
reagents and to Tsuyoshi Akagi and Ray Birge for helpful discussions of
the work and manuscript. We also thank Adelaide Aquaviva for secretarial work.
This study was supported by NIH grant CA44356 and by Council for
Tobacco Research grant 4438 R1. M.M.G. is a recipient of a postdoctoral
fellowship from the Medical Research Council of Canada.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: The Rockefeller
University, Box 169, 1230 York Ave., New York, NY 10021. Phone: (212) 327-8802. Fax: (212) 327-7943. E-mail:
saburo{at}rockvax.rockefeller.edu.
| |
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Molecular and Cellular Biology, February 1999, p. 1171-1181, Vol. 19, No. 2
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Abstract
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