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Mol Cell Biol, February 1998, p. 742-752, Vol. 18, No. 2
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Definition of the Role of Tyrosine Residues of the
Common 
Subunit Regulating Multiple Signaling Pathways of
Granulocyte-Macrophage Colony-Stimulating Factor Receptor
Tohru
Itoh,1,2
Rui
Liu,1
Takashi
Yokota,2
Ken-ichi
Arai,1 and
Sumiko
Watanabe1,*
Department of Molecular and Developmental
Biology1 and
Department of Stem Cell
Regulation,2 The Institute of Medical Science,
The University of Tokyo, Minato-ku, Tokyo 108, Japan
Received 15 May 1997/Accepted 30 October 1997
 |
ABSTRACT |
Granulocyte-macrophage colony-stimulating factor (GM-CSF) induces
various functions, including the proliferation and differentiation of a
broad range of hematopoietic cells. We previously reported that at
least two distinct pathways are involved in human GM-CSF receptor
signaling; both require the box 1 region of the common 
subunit
(c). This region is essential for the activation of JAK2, which is
necessary for all the biological functions of GM-CSF. The activation of
JAK2 by GM-CSF leads to rapid tyrosine phosphorylation of cellular
proteins, including the c. However, the significance of c
phosphorylation with regard to the regulation of signaling molecules
and the expression of GM-CSF functions is less well understood. Here we
investigated the role of the cytoplasmic tyrosine residues of the c
by using a series of c mutants expressed in murine BA/F3 cells. A
mutant c with all eight cytoplasmic tyrosines converted to
phenylalanine (Fall) activated JAK2 but not SHP-2, MAPK cascades,
STAT5, or the c-fos promoter in BA/F3 cells, and it did not
effectively induce proliferation. Adding back each tyrosine to Fall
revealed that Tyr577, Tyr612, and Tyr695 are involved in the activation
of SHP-2, MAPK cascades, and c-fos transcription, while
every tyrosine, particularly Tyr612, Tyr695, Tyr750, and Tyr806,
facilitated STAT5 activation. Impaired growth was also restored, at
least partly, by any of the tyrosines. These results provide evidence
that c tyrosines possess distinct yet overlapping functions in
activating multiple signaling pathways induced by GM-CSF.
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INTRODUCTION |
Cytokines have specific biological
functions, including proliferation, differentiation, and functional
modulation, in target cells expressing their cognate receptors
(2). Thus, most cytokine receptors are coupled with multiple
signaling pathways, which act in concert to govern the functional
specificity of a particular cytokine. How each cytokine regulates
multiple signals downstream of its receptor is less well understood.
Although most cytokine receptors do not possess intrinsic tyrosine
kinase domains, they do interact with one or more nonreceptor tyrosine
kinases. Stimulation with their cognate ligands results in rapid and
reversible tyrosine phosphorylation of multiple proteins, including the
receptors themselves (43). The importance of tyrosine phosphorylation in cytokine signaling has been suggested by findings from various experiments in which tyrosine kinase inhibitors were used.
Many signaling molecules with SH2 (Src homology 2) and/or PTB
(phosphotyrosine binding) domains, such as Shc, SHPs (SH2-containing protein tyrosine phosphatases), and signal transducers and activators of transcription (STATs), have been reported to be recruited onto various cytokine receptors following ligand stimulation
(43). As is the case for growth factor receptors with an
intrinsic tyrosine kinase domain, tyrosine residues of cytokine
receptors are likely to play critical roles in regulating downstream
signaling pathways by being phosphorylated and hence by providing
specific recognition motifs for SH2 domain and/or PTB domain-containing
proteins.
Granulocyte-macrophage colony-stimulating factor (GM-CSF) is a
pleiotropic cytokine which supports proliferation, survival, and
differentiation of hematopoietic progenitor cells; it also enhances the
multiple functions of mature neutrophils, macrophages, and eosinophils
(4, 14). A functional, high-affinity receptor for GM-CSF is
composed of 
and subunits, both belonging to the type I cytokine
receptor superfamily (or hematopoietin receptor family) (5, 15,
19, 23). The subunit, which is also shared by the interleukin
3 (IL-3) and IL-5 receptors (and is thereby termed the common subunit [c]), has a relatively large cytoplasmic domain and plays
a pivotal role in signal transduction (30).
GM-CSF binding induces the formation of a complex between and subunits, which then triggers the activation of several tyrosine
kinases, including JAK2 (17, 37, 45). A series of
experiments with a dominant-negative type of JAK2 revealed that the
activity of JAK2 is necessary for all the biological functions
expressed by GM-CSF (46). For JAK2 activation, the membrane-proximal region of the c containing the box 1 motif is
necessary and sufficient. GM-CSF induces in target cells the expression
of early-response genes, such as c-fos, c-jun,
and c-myc (30). For induction of the
c-fos gene, not only JAK2 activation but also a
membrane-distal region of the c containing several tyrosine residues
is required (22). Since GM-CSF stimulation results in
tyrosine phosphorylation of the receptor c subunit (11,
39) as well as proteins with SH2 and/or PTB domain(s), such as
Shc, SHP-2, Vav, c-Cbl, and STAT5 (29, 34, 35, 41, 50), a
possible role of the c tyrosines in signaling was considered. We
reported that GM-CSF-induced activation of the c-fos
promoter by 589, a truncated mutant c, was significantly
diminished by substitution of a single tyrosine at position 577 (Tyr577), thereby indicating an important role of this tyrosine in
signaling (22). However, the full-length c with the same
mutation at Tyr577 transduced signals sufficient to activate the
c-fos promoter, suggesting that other functional domains,
probably tyrosine residues, also transmit signals. Tyrosine
phosphorylation of SHP-2 (previously termed PTP1D, SH-PTP2, or Syp)
(1), a phosphotyrosine phosphatase proposed to be involved
in Ras activation (7, 26), correlated well with this
phenomenon; that is, SHP-2 phosphorylation was mediated either by
Tyr577 or by other functional domains independent of this tyrosine.
Although the significance of tyrosine phosphorylation of SHP-2 in
Ras activation remains to be determined, it results in the association
of SHP-2 with an adapter molecule, GRB2 (7, 26). These
results suggest the existence of multiple pathways from the c to
c-fos transcription, probably through Ras, but the
functional domain, other than Tyr577, that is responsible for these
events remains to be clarified.
To better understand the pathways and the regulatory mechanism of
GM-CSF signaling, we examined the roles of cytoplasmic tyrosines of the
human c using various mutants with one or more of these residues
replaced by phenylalanine. The signaling potential of these mutants was
analyzed by reconstituting high-affinity receptors in combination with
the wild-type subunit in murine BA/F3 cells. Our evidence shows
that all eight c tyrosines play critical roles in transmitting
GM-CSF-induced signals for cell proliferation, with each one possessing
distinct yet overlapping functions.
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MATERIALS AND METHODS |
Cells and culture.
A murine interleukin-3 (mIL-3)-dependent
pro-B-cell line, BA/F3, was maintained in RPMI 1640 medium supplemented
with 5% fetal calf serum, 50 U of penicillin per ml, 50 µg of
streptomycin per ml, and 0.25 ng of mIL-3 per ml. Factor depletion was
done with the same medium but without mIL-3 for cultures maintained at
37°C for 5 to 6 h. Endogenous murine c (AIC2B) in BA/F3 cells
can functionally interact with the human GM-CSF (hGM-CSF) receptor (hGM-CSFR) subunit at high concentrations (100 ng/ml or more) of
hGM-CSF and support proliferation (23). In this study, we used 10 ng of hGM-CSF per ml for stimulation unless otherwise indicated. Purified recombinant hGM-CSF produced in Escherichia coli was provided by Schering-Plough Corp. mIL-3 expressed in the
silkworm (Bombyx mori) was purified as described previously (31).
Antibodies.
Rat monoclonal antibody against the human c,
5A5, was prepared as described previously (49) and used for
fluorescence-activated cell scanning (FACS) analysis.
Antiphosphotyrosine monoclonal antibody (clone 4G10; 05-321) and
antiserum against JAK2 (06-255) were obtained from Upstate
Biotechnology, Inc. (Lake Placid, N.Y.), and antisera against the
hGM-CSFR subunit (sc-458), SHP-2 (sc-280), Raf-1 (sc-227), ERK2
(sc-154), and JNK1 (sc-474) were obtained from Santa Cruz
Biotechnology, Inc. (Santa Cruz, Calif.). Rabbit polyclonal antibody
against STAT5 (N1) was kindly provided by Hiroshi Wakao (Helix Research
Institute, Kisarazu, Japan).
Plasmids.
The c-fos promoter-luciferase gene
fusion plasmid contains the human c-fos promoter fragment
(
404 to +41) fused to the luciferase fragment and was constructed as
described previously (48). A serum response element
(SRE)-chloramphenicol acetyltransferase (CAT) construct containing a
25-bp oligonucleotide of the c-fos SRE site inserted
upstream of the mouse IL-3 promoter linked to the CAT gene
(13) and a -casein promoter-luciferase construct consisting of a luciferase gene under the control of a minimal -casein promoter (34) were kindly provided by Kozo
Kaibuchi (Nara Advanced Institute of Science and Technology, Ikoma,
Japan) and Hiroshi Wakao (Helix Research Institute), respectively. A plasmid encoding the glutathione S-transferase (GST)-c-Jun
fusion protein [pGEX2T-cJun(1-223)] (20) was a kind gift
from Michael Karin (University of California, San Diego).
The hGM-CSFR c (KH97) cDNA was originally cloned into the pME18S
vector as described previously (19). The c mutants used in this study were constructed by introducing point mutations by use of
sequential PCR steps (3) with appropriately designed oligonucleotide primers. Tyrosine-coding codons TAC (at 450, 452, 577, 612, and 866) and TAT (at 695, 750, and 806) were changed to
phenylalanine-coding codons TTC and TTT, respectively. These PCR-amplified fragments, alone or in combination, were used to replace
the tyrosine-containing sequences of the wild-type c in the pME18S
vector by use of intrinsic restriction enzyme sites within the cDNA.
The accuracy of all the nucleotide sequences of the fragments derived
from the PCR was confirmed by dideoxy sequencing with an automated
sequencer (Applied Biosystems Inc.).
Transient transfection and reporter gene assays.
Plasmid
DNAs were transiently transfected into BA/F3 cells by electroporation.
For each transfection, 3 µg of various c mutant cDNAs or control
vector (pME18S), in combination with either
c-fos-luciferase (3 µg), SRE-CAT (10 µg), or
-casein-luciferase (15 µg), was used. BA/F3 cells which stably
expressed the wild-type hGM-CSFR subunit (3 × 106
cells) were washed twice with OPTI-MEM (Life Technologies, Inc.), resuspended in 200 µl of OPTI-MEM, and then mixed with plasmid DNAs.
An electronic pulse was given with a Gene Pulser (Bio-Rad) set at 960 µF and 200 V. Cells were recovered, maintained in complete medium for
about 12 h, and then separated into three aliquots. After factor
depletion for 6 h in a mIL-3-free medium containing 5% fetal calf
serum, the cells were stimulated with hGM-CSF (10 ng/ml), mIL-3 (1 ng/ml), or no cytokine and then harvested. Proteins were extracted from
the cells by three cycles of freezing and thawing. The protein
concentration was determined with bicinchoninic acid protein assay
reagent (Pierce, Rockford, Ill.) according to the manufacturer's
instructions. Luciferase activity was measured with a luminometer
(Lumat model LB9501; Berthold Japan K. K., Tokyo, Japan) and luciferase
assay substrate (Promega, Madison, Wis.). CAT activity was measured by
a diffusion assay as described previously (40). Data were
subjected to a statistical analysis, and the P values were
determined by Scheffe's multiple-comparison test. P < 0.05 was considered statistically significant.
Establishment of stable transfectants.
The expression
plasmid for the c (13.5 µg) was transfected together with the
pME18S vector containing a neomycin resistance gene (1.5 µg) by
electroporation into BA/F3 cells which stably expressed the wild-type
hGM-CSFR subunit as described previously (20). After
selection with G418 (1 mg/ml) for about 10 days, surface expression of
the transfected c gene products of the G418-resistant clones was
confirmed by FACScan (Becton Dickinson) flow cytometry with anti-c
antibody 5A5. At least two independent clones were established for each
of the c mutants, and these clones were used in this study.
Ligand binding assay.
BA/F3 transfectants were incubated
with 125I-Bolton-Hunter-labeled recombinant hGM-CSF (NEN
Life Science) at 4°C for 2 h in the presence or absence of a
100-fold excess of unlabeled hGM-CSF in Hanks' balanced salt solution
(Life Technologies) containing 0.01% bovine serum albumin and 0.02%
NaN3. Cell-bound 125I-hGM-CSF was separated
from the free ligand by centrifugation through an oil layer
(di-n-butyl phthalate-dioctyl phthalate [1:1.5]; Nacalai
Tesque, Inc., Kyoto, Japan). The radioactivities associated with the
cell-bound and free fractions were determined with a gamma counter
(model 5550; Packard).
Preparation of protein samples.
To analyze tyrosine
phosphorylation of JAK2, SHP-2, or STAT5, immunoprecipitation was done
with the corresponding antibody as described previously
(22).
For a mobility shift assay of Raf-1 or ERK2, total cell lysates of
BA/F3 transfectants were prepared as follows. Factor-deprived
cells
were resuspended in factor-free medium at 10
6 cells/ml and
then transferred into 1.5-ml tubes. The cells were
incubated at 37°C
for 30 min and then either left unstimulated
or stimulated with 10 ng
of hGM-CSF per ml. After stimulation,
the cells were precipitated by a
brief centrifugation and then
lysed in lysis buffer A (50 mM Tris-HCl
[pH 8.0], 150 mM NaCl,
1% Triton X-100, 30 mM sodium pyrophosphate,
1 mM sodium orthovanadate,
50 mM NaF, 1 mM phenylmethylsulfonyl
fluoride [PMSF], 2 µg of
leupeptin per ml, 1 µg of pepstatin A
per ml) for 1 h at 4°C.
Cell lysates were centrifuged to remove
the insoluble material,
and the supernatants were mixed with an equal
volume of 2× sodium
dodecyl sulfate (SDS)-polyacrylamide gel
electrophoresis (PAGE)
sample buffer (2× SDS-PAGE sample buffer is 125 mM Tris-HCl [pH
6.8], 4% SDS, 20% glycerol, 2% 2-mercaptoethanol,
and 0.01 mg
of bromophenol blue per ml), boiled for 5 min, and then
subjected
to SDS-PAGE.
Western blot analysis.
Protein samples were electrophoresed
on an SDS-polyacrylamide gel, electrophoretically transferred onto an
Immobilon polyvinylidene difluoride membrane (Millipore), and then
subjected to Western blot analysis with appropriate antibodies and
enhanced chemiluminescence detection reagent (Amersham) as described
previously (20).
JNK assay.
c-Jun N-terminal kinase/stress-activated protein
kinase (JNK) activity was determined by an in vitro kinase assay with
purified recombinant GST-c-Jun as a substrate as described previously
(28). Briefly, factor-deprived BA/F3 transfectants (3 × 106 cells) were either left unstimulated or stimulated
with 10 ng of hGM-CSF per ml at 37°C. Cells were lysed in lysis
buffer B (20 mM Tris-HCl [pH 7.5], 150 mM NaCl, 1 mM EDTA, 0.5%
Nonidet P-40, 1 mM sodium orthovanadate, 1 mM PMSF) at 4°C for 1 h. Cell lysates were centrifuged to remove the insoluble material, and then endogenous JNK was immunoprecipitated by incubation with a
polyclonal antibody prebound to protein A-Sepharose (Pharmacia Biotech,
Inc.) at 4°C for 2 h. The immunocomplexes were washed twice with
lysis buffer B and twice with kinase assay washing buffer (20 mM HEPES
[pH 7.5], 50 mM NaCl, 2.5 mM MgCl2, 0.1 mM EDTA, 0.05%
Triton X-100). The kinase reaction was initiated by the addition of
kinase buffer (20 mM HEPES [pH 7.5], 20 mM MgCl2, 20 mM
-glycerol phosphate, 1 mM sodium orthovanadate, 20 µM
dithiothreitol, 20 µM ATP) containing 1 µg of purified
GST-c-Jun(1-223) and 25 µM [
-32P]ATP (10 Ci/mmol)
to a final volume of 20 µl. After 20 min of incubation at 30°C, the
reaction was terminated by the addition of SDS-PAGE sample buffer and
boiling for 5 min. Samples were separated by SDS-PAGE, and the
phosphorylation of GST-c-Jun was examined with a FUJI image analyzer
(model BAS-2000).
Cell proliferation assays.
Short-term cell proliferation was
measured by a colorimetric assay with
3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT),
originally developed by Mosmann (32), as described previously (22).
To analyze long-term proliferation, BA/F3 transfectants were deprived
of mIL-3 for 6 h and then cultured in the absence or
presence of
either hGM-CSF (10 ng/ml) or mIL-3 (1 ng/ml). Viable
cell numbers were
counted by a trypan blue dye exclusion assay.
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RESULTS |
Multiple tyrosine residues transmit signals leading to activation
of the c-fos promoter.
We have found that
GM-CSF-induced activation of SHP-2 and the c-fos promoter is
mediated by Tyr577 as well as by other functional residues of the c
located distal to amino acid 589 (22). This distal region
contains five tyrosine residues (Fig. 1).
The c also has two more tyrosines within its cytoplasmic domain
(thus, eight in total) just adjacent to the membrane-spanning region (Fig. 1). Their functional significance has not been investigated. To
search for the possible involvement of these c tyrosines in mediating GM-CSF signaling, we carried out a mutational analysis of all
eight cytoplasmic tyrosines of the c by phenylalanine substitution.
The potential of the c mutants to transduce signals was analyzed by
reconstituting high-affinity GM-CSF receptors with the wild-type human
subunit in mIL-3-dependent BA/F3 cells.
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FIG. 1.
Schematic structures of the c mutants used in this
study. The structures of the wild-type c (boxed) and the c
mutants are shown, with extracellular portions abbreviated. Y and F,
tyrosines and introduced phenylalanines, respectively (their amino acid
positions are indicated); TM, transmembrane region; 1 and 2, box 1 and
box 2 motifs, respectively. Note that the F3 mutant was previously
termed wild;Y577F (22, 46).
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We first needed to know the requirement of
c tyrosines for
activation of the c-
fos promoter, and for this we used a
transient
transfection assay. A reporter plasmid carrying the
c-
fos promoter
fused to the luciferase gene was
cotransfected with receptor cDNAs.
After stimulation with hGM-CSF, cell
lysates were prepared, and
their luciferase activities were determined
(Fig.
2). Substitution
of all eight
tyrosines together (the Fall mutant; Fig.
1) remarkably
diminished the
potential of the
c to transduce c-
fos promoter
activation
signals. In contrast, all of the mutants containing
only a single
mutated tyrosine, with the remaining residues intact
(the F series
mutants; Fig.
1), activated the c-
fos promoter,
which means
that all of the individual tyrosine residues are dispensable
for
c-
fos promoter activation. Thus, hGM-CSF-induced activation
of the c-
fos promoter is mediated through multiple
cytoplasmic
tyrosines of
c.
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FIG. 2.
Multiple tyrosine residues transmit signals leading to
activation of the c-fos promoter. Activation of the
c-fos promoter by each c mutant was measured by a
transient transfection assay. The c-fos promoter-luciferase
fusion construct was cotransfected with mutant c cDNA into BA/F3
cells expressing the wild-type hGM-CSFR subunit as described in
Materials and Methods. After 6 h of factor depletion, cells were
left unstimulated () or were stimulated with 10 ng of hGM-CSF per ml
or 1 ng of mIL-3 per ml for 6 h at 37°C. Cell lysates were
prepared, and their luciferase activities were measured with a
luminometer. The c-fos promoter activity was calculated by
dividing the luminescence intensity (relative light units per minute
per microgram of total protein) of cells with no stimulation or hGM-CSF
stimulation (stim.) by that of cells with mIL-3 stimulation and is
presented as a percentage of that for the wild-type c. All values
are the averages of at least three experiments, and standard deviations
are shown as error bars. Statistical significances of the differences
in the c-fos promoter activities between hGM-CSF-stimulated
samples were as follows: wild-type c and Fall or any of the Y series
mutants except for Y3, significant at P < 0.01; Y3 and
Y4 or Y5, significant at P < 0.01; and Y4 and Y5, not
significant.
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We then constructed a series of mutants, namely, the Y series mutants
(Fig.
1); each of these mutants contains only a single
intact tyrosine
residue, with the remaining tyrosines mutated.
Using these Y series
mutants, we examined whether each of the
c tyrosine residues alone
could transmit signals leading to activation
of the c-
fos
promoter. As shown in Fig.
2, the Y3 mutant, which
possesses Tyr577 as
the sole cytoplasmic tyrosine, activated the
c-
fos promoter
to a level comparable to that seen with the wild-type
c, consistent
with results obtained previously for truncation
mutant
589
(
22). In addition to the Y3 mutant, Y4 and Y5, possessing
Tyr612 and Tyr695, respectively, also activated the promoter partially,
albeit above the basal level. Therefore, three distinct tyrosine
residues within the
c, namely, Tyr577, Tyr612, and Tyr695, can
independently transduce signals activating the c-
fos
promoter.
Activation of JAK2 does not require c tyrosine residues.
To
assess the relationship of various signaling molecules involved in
GM-CSF signaling with the c tyrosines, we established stable
transfectants of BA/F3 cells expressing the hGM-CSFR composed of the
wild-type subunit and a mutant c subunit. Surface expression of
the exogenously introduced receptors was examined by FACS analysis, and
we confirmed that the levels of expression of both and c subunits were not significantly different among the transfectants (Fig.
3). To confirm that the c mutants used
in this study are capable of reconstituting high-affinity receptors, we
performed ligand binding assays using 125I-labeled hGM-CSF.
The Fall mutant clones exhibited high-affinity binding sites for
hGM-CSF, with Kd values of 76 to 90 pM,
comparable to those obtained with the wild-type human c
(Kd, 92 pM). These results indicate that the
c tyrosine residues are not required for the formation of
high-affinity receptors for hGM-CSF.
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FIG. 3.
Surface expression of the exogenously introduced
hGM-CSFR subunits on BA/F3 transfectants. BA/F3 stable transfectants
were incubated with either antibodies against the hGM-CSFR and c
subunits (thick lines in left and right panels, respectively) or
isotype control antibodies (thin lines). Cells were then stained with
appropriate fluorescein isothiocyanate-conjugated secondary antibodies
and subjected to FACS analysis. Surface expression of the F series
mutants of the c was also examined and confirmed to occur at similar
levels (data not shown). Note that two or more stable clones were
established for each of the mutants and that the results for one
representative clone are shown here.
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First, we checked the activation of tyrosine kinase JAK2, which is
considered to be an initial step in receptor activation.
BA/F3 stable
transfectants were stimulated with hGM-CSF, and immunoprecipitation
was
performed with an anti-JAK2 antibody. Tyrosine phosphorylation
of JAK2
was analyzed by Western blot analysis with an antiphosphotyrosine
antibody. As shown in Fig.
4, JAK2 was
activated by all of the
c mutants, including Fall, which contains no
cytoplasmic tyrosines.
Therefore,
c tyrosine residues are not
required for JAK2 activation.
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FIG. 4.
Activation of JAK2 does not require c tyrosine
residues. Factor-deprived BA/F3 stable transfectants (107
cells/sample) were left unstimulated or were stimulated with 10 ng of
hGM-CSF per ml for 5 min at 37°C. Cells were lysed, and
immunocomplexes with anti-JAK2 antibodies were precipitated. Protein
samples were separated by SDS-PAGE, transferred onto polyvinylidene
difluoride membranes, and subjected to Western blot (WB) analysis with
antibodies against phosphotyrosine (4G10, left) or JAK2 (right). IP,
immunoprecipitation.
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Tyr577, Tyr612, and Tyr695 induce SHP-2 phosphorylation and
activate the Raf-1 and ERK2 pathway leading to the c-fos
SRE site.
In earlier work, we analyzed two signaling molecules,
Shc and SHP-2, which function as positive regulators in Ras activation. We found that Tyr577 is essential for tyrosine phosphorylation of Shc,
whereas that of SHP-2 is mediated by Tyr577 as well as by other
functional sites (22). To determine the possible involvement of SHP-2 with Tyr612 and/or Tyr695, both of which positively regulate c-fos promoter activation signals, tyrosine phosphorylation
of SHP-2 in BA/F3 transfectants expressing various c mutants was analyzed by immunoprecipitation and Western blot analyses (Fig. 5A).
Among the Y series mutants, Y4 induced tyrosine phosphorylation of
SHP-2 at a level similar to that induced by the wild-type c. SHP-2
phosphorylation was also induced by Y3 and Y5, although at a slightly
lower level. This phosphorylation correlated with coimmunoprecipitation
of the adapter protein GRB2 with SHP-2, as revealed by reprobing of the
same membrane with an anti-GRB2 antibody, thereby implying a
relationship with Ras activation. These observations show that Tyr612
and Tyr695, in addition to Tyr577, can induce tyrosine phosphorylation
of SHP-2 and its subsequent association with GRB2.
To confirm that SHP-2 phosphorylation results in activation of the Ras
pathway, we examined the activation of molecules known
to function
downstream of Ras. We analyzed the phosphorylation
of serine/threonine
kinase Raf-1 by looking for a mobility shift
in SDS-PAGE. Total cell
lysates were prepared from hGM-CSF-treated
cells and separated by
SDS-PAGE, followed by Western blot analysis
with an anti-Raf-1
antibody. As shown in Fig.
5B, the Y3,
Y4,
and Y5 mutants, which induced SHP-2 phosphorylation, also induced
Raf-1 phosphorylation. We also examined the phosphorylation of
ERK2, a
member of the mitogen-activated protein kinase (MAPK)
family, again by
looking for a mobility shift in SDS-PAGE. The
result obtained was
similar to that for the phosphorylation of
Raf-1 (Fig.
5C). The Y3, Y4,
and Y5 mutants, but no other mutants,
were capable of inducing the
phosphorylation of ERK2. Our findings
support the model that SHP-2
functions as a positive regulator
for activation of the Ras, Raf-1, and
ERK2 pathway in GM-CSF signaling.
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FIG. 5.
Tyr577, Tyr612, and Tyr695 activate SHP-2 and the Raf-1
and ERK2 pathway leading to the c-fos SRE site. (A) Tyrosine
phosphorylation of SHP-2 and its association with GRB2. Factor-deprived
BA/F3 stable transfectants (107 cells/sample) were
stimulated with 10 ng of hGM-CSF per ml at 37°C for the indicated
times. Cells were lysed, and immunocomplexes with anti-SHP2 antibodies
were precipitated. Protein samples were separated by SDS-PAGE,
transferred onto polyvinylidene difluoride (PVDF) membranes, and
subjected to Western blot (WB) analysis with antibodies against
phosphotyrosine (4G10, left), SHP-2 (center), or GRB2 (right). IP,
immunoprecipitation. (B and C) Phosphorylation of Raf-1 and ERK2
examined by mobility shift in SDS-PAGE. Factor-deprived BA/F3 stable
transfectants (105 cells/sample) were stimulated with 10 ng
of hGM-CSF per ml at 37°C for the indicated times. Total cell lysates
were prepared, separated by SDS-PAGE, transferred onto PVDF membranes,
and subjected to Western blot analysis with antibodies against Raf-1
(B) or ERK2 (C). The band marked with a circled P in each panel
corresponds to the phosphorylated molecule. (D) Activation of
transcription through the SRE site determined by a transient
transfection assay. A plasmid containing the c-fos SRE site
fused to the CAT coding region was cotransfected with mutant c cDNA
into BA/F3 cells expressing the wild-type hGM-CSFR subunit. After
6 h of factor depletion, cells were left unstimulated or were
stimulated with 10 ng of hGM-CSF per ml or 1 ng of mIL-3 per ml for
10 h at 37°C. Cell lysates were prepared, and their CAT
activities were measured by a diffusion assay. Data were normalized by
dividing the CAT activity (counts per minute per microgram of protein)
of cells with no stimulation or hGM-CSF stimulation (stim.) by that of
cells with mIL-3 stimulation and are presented as a percentage of that
for the wild-type c. All values are the averages of three
experiments, and standard deviations are shown as error bars.
Statistical significances of the differences in the SRE-CAT activities
between hGM-CSF-stimulated samples were as follows: wild-type c and
any of the mutants except for Y3, significant at P < 0.05; Fall and Y3, Y4, or Y5, significant at P < 0.05;
Y3 and Y4 or Y5, significant at P < 0.05; and Y4 and
Y5, not significant.
|
|
Among the target molecules to be phosphorylated by activated
extracellular signal-regulated kinases (ERKs) in the nucleus
are the
ternary complex factors (TCFs) (
42). TCFs bind to the
SRE in
the c-
fos promoter region and activate transcription of
the
c-
fos gene. To determine if activation signals leading to
the c-
fos promoter from
c tyrosines involve the Ras
pathway and
the SRE site, we performed transient transfection assays
using
the SRE-CAT construct as a reporter gene. The result (Fig.
5D)
was an expression pattern for the reporter gene similar to that
obtained with the c-
fos-luciferase reporter gene (Fig.
2).
The
Y3 mutant activated transcription through the SRE site at a level
comparable to that seen with the wild-type
c. In addition, partial
but clearly evident activation was also observed with the Y4 and
Y5
mutants. These results imply that the activation of c-
fos
transcription
by GM-CSF is mediated mainly through the SRE site.
Tyr577, Tyr612, and Tyr695 activate JNK.
We recently obtained
evidence that hGM-CSF activates JNK, a member of the MAPK family, in
BA/F3 transfectants, and this activation requires a membrane-proximal
region including box 1 and a more distal region of the c
(28). We also showed in that report that any one of the F
series mutants, but not the Fall mutant, activates JNK, which means
that multiple tyrosines play a role in the activation of JNK. To
further delineate the mechanism of JNK activation by GM-CSF, we
examined the requirement for receptor tyrosine residues using the Y
series mutants (Fig. 6). JNK was immunoprecipitated from cell lysates after GM-CSF treatment, and an in
vitro kinase assay was performed with GST-c-Jun as a substrate. Among
the Y series mutants, Y3, Y4, and Y5 were capable of activating JNK.
Thus, GM-CSF regulates the JNK pathway through the same set of c
tyrosines as that used for the ERK pathway.
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FIG. 6.
Tyr577, Tyr612, and Tyr695 activate JNK. Factor-deprived
BA/F3 stable transfectants (8 × 106 cells/sample)
were stimulated with 10 ng of hGM-CSF per ml at 37°C for the
indicated times. Cells were lysed, and immunocomplexes with anti-JNK1
antibodies were precipitated. Protein samples were divided into two
portions, and one part (equivalent to 3 × 106 cells)
was subjected to the in vitro kinase assay with GST-c-Jun as a
substrate (left) as described in Materials and Methods. The other part
of the samples (equivalent to 5 × 106 cells) was used
for Western blot (WB) analysis to determine JNK1 protein levels
(right). The circled P means that the bands correspond to the
phosphorylated GST-c-Jun. IP, immunoprecipitation.
|
|
Tyrosine residues of the c are required for STAT5
activation.
Among the STAT family members, STAT5A and STAT5B are
activated by GM-CSF in BA/F3 cells, and in a previous study with
C-terminally truncated mutants, it was noted that this activation
seemed to be independent of c tyrosine residues (34).
However, the possible involvement of the most proximal tyrosines
(Tyr450 and Tyr452) would need to be ruled out. With other cytokines,
such as IL-2, erythropoietin, or growth hormone, the activation of
STAT5 has been shown to depend on specific tyrosine residues in their
receptor subunits (10, 16, 18, 24, 27, 38). Thus, we
examined the possibility that the c tyrosines also play a role in
the activation of STAT5 by GM-CSF. Tyrosine phosphorylation of STAT5, which is required for dimer formation, was assessed by
immunoprecipitation and subsequent Western blot analysis. The antibody
used here recognizes both STAT5A and STAT5B. As shown in Fig.
7A, the induction of STAT5
phosphorylation was significantly diminished, although not completely
abrogated, when all eight tyrosines of the c were substituted
(Fall), thereby demonstrating the requirement of tyrosine residues for
c-mediated phosphorylation of STAT5. Similar results were obtained
in gel shift assays with the mammary gland factor (MGF) binding site in
the -casein promoter as a probe (data not shown). To further
delineate the tyrosines involved, we analyzed the Y series mutants and
found that Y4, Y5, Y6, and Y7 were capable of inducing STAT5
phosphorylation to the same extent as wild-type c. Moreover, the
level of phosphorylation induced by the Y12, Y3, and Y8 mutants was
slight but was significantly higher than that induced by Fall. These
data suggest that any of the eight tyrosines can independently
contribute to the activation of STAT5, albeit to different extents.
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FIG. 7.
Tyrosine residues of the c are required for STAT5
activation. (A) Tyrosine phosphorylation of STAT5. Factor-deprived
BA/F3 stable transfectants (5 × 106 cells/sample)
were stimulated with 10 ng of hGM-CSF per ml at 37°C for the
indicated times. Cells were lysed, and immunocomplexes were
precipitated with anti-STAT5 antibodies. Protein samples were separated
by SDS-PAGE, transferred onto polyvinylidene difluoride membranes, and
subjected to Western blot (WB) analysis with antibodies against
phosphotyrosine (4G10, left) or STAT5 (right). Two independent stable
clones for each of the Y series mutants and three for the Fall mutant
were analyzed and showed essentially the same results (not shown). IP,
immunoprecipitation. (B) Activation of the -casein promoter by each
c mutant was measured by a transient transfection assay. The
-casein promoter-luciferase fusion construct was cotransfected with
mutant c cDNA into BA/F3 cells expressing the wild-type hGM-CSFR subunit as described in Materials and Methods. After 6 h of factor
depletion, cells were left unstimulated or were stimulated with 10 ng
of hGM-CSF per ml or 1 ng of mIL-3 per ml for 6 h at 37°C. Cell
lysates were prepared, and their luciferase activities were measured
with a luminometer. The -casein promoter activity was calculated by
dividing the luminescence intensity (relative light units per minute
per microgram of total protein) of cells with no stimulation or hGM-CSF
stimulation (stim.) by that of cells with mIL-3 stimulation and are
presented as a percentage of that for the wild-type c. All values
are the averages of three experiments, and standard deviations are
shown as error bars. Statistical significances of the differences in
the -casein promoter activities between hGM-CSF-stimulated samples
were as follows: wild-type c and any of the mutants, significant at
P < 0.05; Fall and Y4, Y5, Y6, or Y7, significant at
P < 0.05; Y12 and Y8, not significant; and Y7 and Y6
or Y8, not significant.
|
|
Since tyrosine phosphorylation may not be sufficient for STAT5 to
induce transcriptional activation, we used a transient transfection
assay and the
-casein promoter-luciferase reporter gene for related
determinations. The transactivation capacity of STAT5 was seen
to
depend on
c tyrosines in a manner similar although not identical
to
that seen for STAT5 phosphorylation. The Fall mutant showed
little
expression of the reporter gene, while all of the Y series
mutants,
except for Y12, were capable of inducing significantly
higher
expression (Fig.
7B). However, we detected no marked difference
between
the Fall and Y12 mutants. The Y4, Y5, Y6, and Y7 mutants
induced STAT5
phosphorylation to similar extents, which were apparently
higher than
that induced by the Y8 mutant (Fig.
7A), yet the transactivation
capacity of Y7 appeared to be weaker than those of Y4, Y5, and
Y6 and
was not significantly different from that of Y8. Nonetheless,
our
results clearly indicate that GM-CSF-induced activation of
STAT5
depends, to a considerable extent, on multiple tyrosine
residues of the
c. As expected, each of the F series mutants
was capable of inducing
transactivation of the
-casein promoter
to a level comparable to
that seen with wild-type
c (data not
shown), indicating that none of
the
c tyrosine residues is indispensable
for this signaling event.
Tyrosine residues of the c are required for a maximal
proliferative response to hGM-CSF.
Studies carried out with a
dominant-negative type of STAT5 suggested that this molecule has a role
in IL-3-induced proliferation (33). As we found that c
tyrosines are important for c-mediated STAT5 activation, we next
asked whether or not they are also involved in transmitting
growth-promoting signals. As shown in Fig.
8, the potential of the c to induce
short-term proliferation of BA/F3 cells, as examined by an MTT assay,
was severely impaired in the absence of all of the cytoplasmic
tyrosines (Fall). This result indicates that the c tyrosines are
necessary for GM-CSF-stimulated proliferation, at least to induce a
maximal response. Further analyses with BA/F3 cells expressing Y series
mutants showed that this deficiency of Fall was restored, at least
partly, by the presence of any one (or two, in the case of Y12) of the
c tyrosines. In particular, the Y3, Y4, and Y5 mutants induced a
relatively higher level of growth response than did the other mutants.
Therefore, each of the c tyrosines can independently and in a
different manner mediate growth-promoting signals.
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FIG. 8.
Tyrosine residues of the c are necessary for a
maximal proliferative response to hGM-CSF. Shown is short-term
proliferation of BA/F3 transfectants expressing the hGM-CSFR subunit together with no c (), the wild-type c (wild),
Fall, or the Y series mutants. The BA/F3 transfectants were factor
deprived for 6 h and then cultured for 24 h in the presence
of 0 to 100 ng of hGM-CSF per ml or 0 to 10 ng of mIL-3 per ml. Cell
growth was examined by the MTT colorimetric assay. The vertical axis
indicates the relative MTT reduction value normalized to the value for
cells incubated with 1 ng of mIL-3 per ml. All values are the averages
of triplicate samples, and standard deviations are shown as error bars.
All of the transfectants exhibited a similar dose-dependent response to
mIL-3 stimulation (not shown). Similar results were obtained in three
separate experiments.
|
|
To determine whether or not the impairment of the Fall mutant in growth
promotion was due to a defect in maintaining cell
viability, we further
examined the long-term proliferation and
survival of BA/F3
transfectants by a trypan blue dye exclusion
assay. In the presence of
10 ng of hGM-CSF per ml, BA/F3 cells
expressing the Fall mutant kept on
proliferating, albeit at a
lower growth rate, and showed no significant
loss of viability
(Fig.
9). The viability
of the cells was maintained at the same
level for more than 1 week
(data not shown). Consistent with this
result, all of the Y series
mutants also possessed the capability
of supporting cell viability
(data not shown).
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FIG. 9.
The Fall mutant can support the survival of BA/F3
transfectants. Shown are long-term proliferation (upper panels) and the
viability (lower panels) of BA/F3 transfectants expressing the hGM-CSFR
subunit together with no c (), the wild-type c (wild),
or the Fall mutant (Fall). Factor-deprived BA/F3 transfectants
(105 cells) were seeded in the absence or presence of
either hGM-CSF (10 ng/ml) or mIL-3 (1 ng/ml). Viable cell numbers were
measured by a trypan blue dye exclusion assay. All values are the
averages of triplicate samples, and standard deviations are shown as
error bars. Three independent stable clones were examined for the Fall
mutant and gave similar results.
|
|
| |
DISCUSSION |
In the present work, we focused attention on cytoplasmic tyrosine
residues within the c and analyzed their function in GM-CSF signaling. Substituting all eight cytoplasmic tyrosines together severely impaired the potential of the c to transduce various signals, thereby indicating the critical requirement of c tyrosines for signaling. Because the Fall mutant still activated JAK2, loss of
this function likely did not result from unfavorable changes in
structural integrity. None of the F series mutants, lacking only one
tyrosine, showed any significant defect in activating the
c-fos promoter or in growth promotion (Fig. 2 and data not shown), consistent with our previous results indicating that
c-fos activation can be mediated independently by either
Tyr577 or other functional residues located C terminal to this tyrosine
(22). Therefore, we constructed the Y series mutants by
adding back each and every tyrosine in the background of the Fall
mutant.
Among the eight tyrosines of the c, three tyrosines, Tyr577, Tyr612,
and Tyr695, are involved in and can individually induce SHP-2
phosphorylation, its association with GRB2, and activation of the
putative downstream Raf and ERK pathway, resulting in transactivation of the c-fos promoter. We and others previously showed that
Tyr577 is necessary for tyrosine phosphorylation of Shc (12,
22), another molecule implicated in the activation of Ras through
the GRB2-Sos complex. Thus, Tyr577 utilizes both Shc and SHP-2 to stimulate this pathway, while Tyr612 or Tyr695 induces the
phosphorylation of only SHP-2. This result may partly account for the
finding that the Y3 mutant can activate the c-fos promoter
sufficiently and more strongly than Y4 and Y5. The c-fos
promoter contains several cis regulatory elements, and our
results strongly suggest that GM-CSF-dependent transcription of
c-fos is mediated mainly through the SRE site. Consistent
with the present results, our recent study done to dissect the
c-fos promoter region also revealed a critical role for the
SRE site in hGM-CSF-induced transcriptional activation (47).
The activation of JNK was also mediated by the same set of c
tyrosines as that needed for the phosphorylation of SHP-2, Raf-1, and
ERK2 and the induction of c-fos transcription, suggesting
that these events are related. It was reported that Ras activation is
necessary but not sufficient for IL-3 stimulation of JNK1
(44). JNKs phosphorylate and hence activate the
transcription factors c-Jun, ATF2, and Elk-1, which is a member of the
TCFs (9, 51). It is thus possible that the JNK pathway is
also involved in GM-CSF-induced activation of the c-fos
promoter through the SRE site.
The activation of STAT5 by GM-CSF was also seen to depend on c
tyrosines, but the requirements differed. The level of STAT5 phosphorylation was dramatically decreased by a lack of all of the c
tyrosines (Fall) but was increased when any one (or two, in the case of
Y12) tyrosine was added back, with each showing a unique extent of
recovery. Interestingly, the Y12 mutant induced a markedly stronger
phosphorylation of STAT5 than did Fall, while these two mutants showed
little transactivation of the -casein promoter. Since the activity
of STAT5 is subject to regulation concerning Ser phosphorylation
(6), the Y12 mutant may not be able to transmit that signal.
Notably, we consistently observed that the Fall mutant could induce low
but detectable levels of STAT5 activation and SHP-2 phosphorylation in
response to GM-CSF stimulation (Fig. 5A and 7A). Since Fall is capable
of activating JAK2 (Fig. 4), it is possible that JAK2 and/or other
tyrosine kinases, which can be activated independently of the c
tyrosine residues, play a substantial role in phosphorylating STAT5 and SHP-2. Nonetheless, efficient phosphorylation can only be accomplished in the presence of the receptor tyrosines by means of recruitment of
these molecules onto the receptor and hence their close proximity to
the kinases.
Our evidence shows that the c tyrosines play critical roles in
transmitting growth-promoting signals, as the Fall mutant was severely
impaired in stimulating cell proliferation. We obtained a similar
result for [3H]thymidine incorporation (45a).
This defect was restored, at least partly, by the presence of any one
of the c tyrosines. Dominant-negative STAT5 inhibits but does not
completely suppress IL-3-driven proliferation of BA/F3 cells, thereby
suggesting an important role for STAT5 in mitogenic signals
(33). Taken together, these findings may indicate that
increased activation of STAT5 by the presence of any one tyrosine
results in improved growth-promoting activity of the Y series mutants.
Although the activation of STAT5 by the Y12 mutant is ambiguous, as
mentioned above, it is possible that even a low level of STAT5
activation is sufficient to accelerate growth promotion, while the
transactivation of the -casein promoter requires a much higher level
of STAT5 activation and/or additional signaling events. Alternatively,
Tyr450 or Tyr452 could stimulate proliferation by recruiting a molecule
other than STAT5. It should be noted that, among the Y series mutants,
Y3, Y4, and Y5 induced relatively higher levels of growth response than
did the other mutants. This finding correlates with the induction of
SHP-2 phosphorylation, MAPK pathway activation, and c-fos
transcription. Thus, these signaling events, although not necessarily
required for growth promotion, may play a role in inducing optimal cell
proliferation under physiological conditions.
In general, specificity in the recognition of a particular
phosphotyrosine residue by an SH2 or PTB domain is predominantly defined by a primary sequence surrounding that residue. Four of the
eight cytoplasmic tyrosines of the c, namely, Tyr612, Tyr750, Tyr806, and Tyr866, possess a leucine and a proline at positions +3 and
+4, respectively, and an acidic residue at position 1 or 2 (Fig.
10). Since these four tyrosines were
all involved in the activation of STAT5, it is conceivable that these
Y-X-X-L-P motifs are recognized by the SH2 domain of STAT5 or of
another adapter molecule which in turn binds STAT5. Consistent with
this suggestion, many of the tyrosines of the erythropoietin (EPO) receptor and the IL-2 receptor subunit involved in STAT5 activation also possess a leucine at position +3 (10, 16, 24, 27, 38).
However, STAT5 was also activated by the other c tyrosines, surrounded by relatively different motifs. It is possible that these
tyrosines recruit STAT5 in different ways, presumably through distinct
adapter proteins. Alternatively, the STAT5 SH2 domain could bind
relatively divergent motifs, including those with and without a leucine
at position +3. This notion is supported by the sequence surrounding
the Tyr694 of STAT5 (Y-V-K-P-Q), which should be recognized by the
STAT5 SH2 domain to form a dimer.
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FIG. 10.
Tyrosine-containing motifs in the human c subunit.
Amino acid sequences surrounding the c tyrosines are aligned, with
signaling molecules activated by each tyrosine on the right. The
conserved residues among four of the eight c tyrosines (the
Y-X-X-L-P motif, bottom) are boxed.
|
|
In the case of SHP-2, our results showed that Tyr577, Tyr612, and
Tyr695 are involved in its phosphorylation. It has been predicted that
the N-terminal SH2 domain of SHP-2 binds to phosphotyrosines followed
by a -branched residue at position +1 and a hydrophobic residue at
+3, comprising the consensus sequence Y-V/I/T-X-V/L/I (8).
In addition, the involvement of residues N terminal and more C terminal
to these residues, especially a hydrophobic residue (leucine,
phenylalanine, or proline) at position +5 and valine, leucine, or
glycine at position 2, in high-affinity binding has also been
suggested (21, 25). The sequence surrounding Tyr612 (L-G-Y612-L-C-L-P-A; Fig. 10) matches these predictions
well; thus, there may be a direct interaction of this tyrosine with
SHP-2. Notably, among the four tyrosines with the Y-X-X-L-P motif
mentioned above, only Tyr612 could induce SHP-2 phosphorylation, while
all four were involved in STAT5 activation, confirming the role of
residues outside the former consensus sequence (Y-V/I/T-X-V/L/I
[8]) in defining the specificity in SHP-2
interactions.
Taken together, STAT5 activation and SHP-2 phosphorylation are mediated
by multiple c tyrosines. The sets of tyrosines required for these
molecules are distinct, yet they overlap. Their surrounding motifs are
not necessarily uniform either. These molecules seem to be regulated
through "redundant" tyrosines of the c. In terms of signaling
molecules that the individual tyrosines activate, it is intriguing that
several c tyrosines have pleiotropic functions rather than a
specific one. This finding is most remarkable with Tyr577, which is
involved in the activation of STAT5 and the phosphorylation of SHP-2
and Shc. With Tyr612 and Tyr695, STAT5 activation and SHP-2
phosphorylation were observed. Further analyses are required to
determine whether each of these molecules can independently interact
with the same tyrosine or whether these molecules associate with
another common molecule which interacts directly with the c
tyrosine, thereby functioning as a docking protein. Alternatively, these molecules might be activated sequentially along the same pathway.
We have no clear evidence of a direct interaction of either STAT5 or
SHP-2 with the c, while a possible interaction between Tyr577 and
the Shc PTB domain has been reported (36). It seems likely
that adapter proteins play a role in recruiting these molecules onto
the c. Therefore, it is of great importance to define the molecules
directly interacting with c tyrosines. These studies, together with
our present data showing the critical roles of the c tyrosines, will
pave the way for a better understanding of the signaling mechanisms of
GM-CSF, IL-3, and IL-5.
| |
ACKNOWLEDGMENTS |
We thank D. Chida for helpful suggestions, K. Hagino for
technical assistance, and M. Ohara and M. Dahl for critical comments on
the manuscript.
This work was supported in part by CREST (Core Research for Evolutional
Science and Technology) of the Japan Science and Technology Corporation
and by a grant-in-aid for scientific research on priority areas from
the Ministry of Education, Science, Sports and Culture of Japan. T.I.
is a recipient of a research fellowship from the Japan Society for the
Promotion of Science for Young Scientists.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Molecular and Developmental Biology, The Institute of Medical Science, The University of Tokyo, 4-6-1, Shirokanedai, Minato-ku, Tokyo 108, Japan. Phone: 81-3-5449-5660. Fax: 81-3-5449-5424. E-mail: sumiko{at}ims.u-tokyo.ac.jp.
| |
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Mol Cell Biol, February 1998, p. 742-752, Vol. 18, No. 2
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Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
