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(Received for publication, July 18, 1995) From the
Phosphorylation and dephosphorylation of Tyr-530 in human c-Src
(Tyr-527 in avian c-Src) is critical in regulating c-Src kinase
activity. So far, it has not been possible to distinguish the active
and inactive forms in vivo. We now report a new monoclonal
antibody that selectively recognizes the active form of c-Src. This
antibody, termed clone 28, recognized a region adjacent to Tyr-530
(Q Using clone 28, we demonstrated
a distinct localization of the active form of c-Src within cultured
normal fibrobast cells. In liver tissue sections, we also examined the
distribution of the active form in embryonic mice. Megakaryocytes were
strongly stained, in contrast to completely negative immunoreactivity
in hepatocytes, reticulocytes, and granulocytes. This result provides
the first direct evidence that c-Src is highly activated in platelets. Src family tyrosine kinases are widely distributed nonreceptor
tyrosine kinases that have a role in many different signal transduction
pathways downstream from various types of receptor in the cell
membrane; however, their exact roles in signal transduction remain
unknown. Src family tyrosine kinases (for reviews, see Hunter(1987),
Cantley et al.(1991), and Bolen et al.(1992)) are
known both from retroviruses that have the ability to transform cells
(Src, Yes, Fgr, and Lck) and from mammalian genomes by the use of DNA
probes for src/yes/fgr (Fyn, Lyn, Hck, Blk, and Yrk). A
comparison of the corresponding cDNA sequences revealed that each
member of this family has a very different sequence in the N-terminal
region (50-80 amino acids from the N terminus). This region is
thought to participate in specific cellular function through binding to
different types of signal transducer (Resh, 1989; Shaw et al.,
1990; Timson-Gauen et al., 1992), although the mechanism of
regulation remains unknown. By contrast, the rest of the sequence is
highly conserved, consisting sequentially of an Src homology (SH) ( Two tyrosine residues, Tyr-419 and Tyr-530 in human c-Src
(corresponding to Tyr-416 and Tyr-527, respectively, in avian c-Src),
can be phosphorylated, and their phosphorylation state influences the
tyrosine kinase activity. Whereas the phosphorylation of Tyr-419 leads
to a dramatic increase in kinase activity (Piwnica-Worms et
al., 1987), the phosphorylation of Tyr-530 negatively regulates
the kinase activity (Cooper et al., 1986). The csk gene product is responsible for the phosphorylation of Tyr-530
(Okada and Nakagawa, 1989; Okada et al., 1991). The mechanism
of regulation involving these tyrosine residues is thought to be
similar for other members of the Src family (Okada et al.,
1991). On the basis of these observations, a model that involves
intramolecular binding between Tyr-530 and the SH2 region was proposed
(Roussel et al., 1991; Superti-Furga et al., 1993;
Sieh et al., 1993). In this widely accepted model, subsequent
signal transduction through direct binding to other proteins or by
tyrosine phosphorylation is assumed to be prevented by this
intramolecular binding. Consequently, the C-terminal region is
important not only in the regulation of tyrosine kinase activity, but
also in the association with SH2-containing proteins. In the present
study, we have generated a monoclonal antibody (mAb) specific for the
C-terminal regulatory domain of c-Src. This mAb selectively recognized
the active form of c-Src as demonstrated by in vitro and in vivo phosphorylation. Several different types of experiment
described here illustrated the usefulness of this mAb. The antibody had
a different range of reactivity in comparison with mAb 327, which has
been widely used for the detection of c-Src and v-Src. In particular,
clone 28 was shown to have high sensitivity to the active form of c-Src
in normal cells and tissues.
Figure 1:
Reactivity of clone 28
and mAb 327 with human platelet lysates. A, Western blotting
with control mouse IgG (lane 1), clone 28 (lane 2),
and mAb 327 (lane 3) in human platelets. B, combined
immunoprecipitation/Western blotting in human platelets. Platelet
lysates were immunoprecipitated with control mouse IgG (lane
1), clone 28 (lanes 2 and 3), and immune
complexes were subjected to electrophoresis for Western blotting by mAb
327 (lanes 1 and 2) or clone 28 (lane
3).
Figure 2:
Detection of phosphorylated proteins from
human platelets. A, in vivo phosphorylation assay.
Platelets were metabolically labeled with
[
Figure 3:
Competition for antibody binding in in
vitro phosphorylation systems. We synthesized a series of short
peptides as illustrated in Table 1and determined their ability
to inhibit immunoprecipitation by clone 28 in the in vitro kinase assay (A). Immunoprecipitation was performed in
the presence of 0.1 mg/ml LEDYFTST (519-526, lane 1),
EPQYQPG (527-533, lane 2), QYQPGENL (529-536, lane 3), QF*QPGENL (529-536, lane 4), or
QYQPGD*Q*T* (529-536, lane 5) or in the absence of
synthetic peptides (lane 6). We also compared the inhibition
of immunoprecipitation caused by the non-phosphorylated peptide
QYQPGENL (B, lanes 2-4) and the corresponding
phosphotyrosine-containing peptide (B, lanes
5-7). The concentration of each peptide was 1 µg/ml (lanes 2 and 5), 10 µg/ml (lanes 3 and 6), or 100 µg/ml (lanes 4 and 7). The
control level was determined in the absence of any peptide (lane
1).
Figure 4:
Phosphopeptide mapping. Excised 60-kDa
bands from lanes 2 (clone 28 precipitate) and 5 (mAb
327 precipitate) in Fig. 2A were subjected to V8
protease partial digestion (A) or cyanogen bromide cleavage (B). Lanes 1 correspond to clone 28 and lanes 2 to mAb 327. Excised V1 and V2 bands from each lane in A were further analyzed by two-dimensional tryptic peptide mapping (C).
We also
performed preabsorption experiments in in vitro and in
vivo systems. Lysates of human platelets metabolically labeled
with [
Figure 5:
Preabsorption of human platelet lysates.
Human platelet lysates were pretreated with control mouse IgG (lanes 1 and lanes 2) or clone 28 (lanes 3).
After preabsorption, lysates were further incubated with clone 28 (lanes 1) or mAb 327 (lanes 2 and lanes 3). In vivo (A) or in vitro (B)
phosphorylation assays were performed as in Fig. 2.
Figure 6:
The distribution of c-Src within normal
rat fibroblast 3Y1 cells. Comparison between clone 28 and mAb 327 in an
immunocytochemical analysis. The 3Y1 cells were stained with clone 28 (A) or mAb 327 (B). Bar, 15
µm.
In order to test the
utility of the clone 28 directly in an in vivo system, we
examined formalin-fixed, paraffin-embedded C3H-mouse fetal liver (16
days) by an immunocytochemical method. Fig. 7clearly shows the
presence of the active form of c-Src in megakaryocytes, but completely
negative immunoreactivity in hepatocytes, reticulocytes, and
granulocytes in the fetal liver. We also detected high level of the
active form in neuronal tissues. (
Figure 7:
Immunoreactive localization of the active
form of c-Src in the liver of developing mouse embryo (16 days).
Sections were stained with clone 28 (A) or normal mouse IgG (B, as a negative control). The active form of c-Src was found
preferentially in inside the plasma membrane of megakaryocytes. Bar, 20 µm.
In order to clarify the activation mechanism of Src family
tyrosine kinases, we set out to produce mAbs that could be used to
distinguish the active and inactive forms of these tyrosine kinases in
various systems. Activation is associated with dephosphorylation of the
tyrosine residue nearest the C terminus (Courtneidge, 1985; Cooper and
King, 1986), and subsequent signal transfer is presumed to involve a
dissociation between this tyrosine-containing region and an SH2 region.
We have generated a single mAb, termed clone 28, that could selectively
recognize the active form of c-Src. We have characterized clone 28 and
demonstrated its usefulness as follows: 1) clone 28 sensitively
detected the active form of c-Src as judged by titration in an in
vitro phosphorylation experiment (Fig. 2); 2) a competition
study using phosphorylated and nonphosphorylated synthetic peptides
confirmed the specificity of clone 28 for the active (Tyr-530
nonphosphorylated) form (Fig. 3); 3) the phosphorylation site of
the clone 28 precipitate was clearly distinguishable from that of the
mAb 327 precipitate (Fig. 4); 4) preabsorption experiments with
clone 28 and mAb 327 in in vitro and in vivo phosphorylation systems suggested that there are at least two
different conformations that retain kinase activity (Fig. 5);
and 5) the distribution of the active form in rodent tissues and
cultured cells could be directly observed by an immunocytochemical
method ( Fig. 6and 7). Cooper and Howell(1993) proposed a new
activation mechanism for Src family tyrosine kinases involving
allosteric activators or inhibitors. They presumed that phosphorylation
of the tyrosine residues might be a consequence, and not a cause, of
changes in activity. Site-directed mutagenesis studies (Hirai and
Varmus, 1990; O'Brien et al., 1990; Seidel-Dugan et
al., 1992) support this notion, because Src could be activated by
introducing mutations in other domains such as SH2 or SH3. The
detection of kinase activity both before and after preabsorption by
clone 28 (Fig. 5) also showed good agreement with this previous
work, since excess clone 28 could not completely immunoprecipitate the
active form, even though this clone was specific for the active form.
Erpel and Courtneidge(1995) also discussed yet another activation
mechanism and proposed three possible pathways to the active form. In platelets, V8 phosphopeptide mapping facilitated further analysis
of the phosphorylation state of the clone 28 and the mAb 327
precipitates: the patterns for both precipitates were virtually
identical (Fig. 4A). Cichowski et al.(1992)
detected Src, Yes, and Fyn, but not Fgr, in thrombin-stimulated human
platelets. They co-precipitated Yes and Fyn with an antibody against
GTP-activating protein, but the member of the Src family responsible
for platelet activation has not been identified. We also investigated
several antibodies against each member of the c-Src family in order to
identify which were active in the platelet system, but none of the
antibodies demonstrated satisfactory sensitivity or specificity.
However, clone 28 could give us valuable information on alterations in
the kinase activity and cellular localization of Src family tyrosine
kinases; such information could help us understand the redundancy and
compensation in vivo among the members of the Src family that
possess the QYQPG motif. Primary cells derived from knockout mice (e.g. src, fyn, and yes) might provide
information about the role of each member of the Src family when tested
with our new antibody. Polyclonal antibodies against the C-terminal
region of c-Src have previously been reported (Courtneidge and Smith,
1984; Cooper and King, 1986). One of these antibodies (Courtneidge and
Smith, 1984) could be used both for the precipitation of the
phosphorylated form of the kinase and for the autophosphorylation
assay. However, there was no mention of cross-reactivity among members
of the Src family. Another antibody (Cooper and King, 1986) stimulated
the kinase activity upon antibody binding and could also be used for
the precipitation of the phosphorylated form. For these polyclonal
antibodies, it is possible that several epitopes coexist, some
containing Tyr-530 and some not. The results obtained with these
antibodies are consistent with our results. Since clone 28 recognized
only a single epitope (adjacent to Tyr-530) and was specific for the
nonphosphorylated, active form, the phosphorylation state of c-Src was
more readily characterized with this antibody. In addition to its
usefulness in biochemical systems, we have also demonstrated the
application of clone 28 in in vivo systems. In particular, Fig. 7clearly shows a restricted distribution of the active form
in megakaryocytes, the progenitors of platelets. The tyrosine kinase
activity of c-Src might be essential for platelet formation in the
fetal liver, because c-Src was activated at all the developmental
stages we observed (data not shown). Our data show good agreement with
previous work, which reported high kinase activity in platelets by an in vitro kinase assay (Oda et al., 1992; Horvath et al., 1992; Clark and Brugge, 1993). In contrast to the
intense staining in established cell lines such as 3Y1 (Fig. 6),
immunohistochemical observations with mouse tissue sections revealed a
restricted distribution even in the fetal stage, where cellular growth
and differentiation actively occur (Fig. 7). These data, taken
together, suggest that c-Src kinase activity would be suppressed in the
steady state and activated transiently by extracellular stimuli in
major tissues. With clone 28, our immunofluorescence studies
demonstrated distinctive staining of c-Src in normal rat cells, whereas
with mAb 327, only a weak, diffuse staining pattern was observed. With
mAb 327, it is very difficult to detect c-Src unless the protein is
overexpressed by gene transfection (David-Pfeuty and Nouvian-Dooghe,
1990; David-Pfeuty et al., 1993; Kaplan et al.,
1994). Our new mAb could provide valuable information about early
events in carcinogenesis and other diseases in which Src family
tyrosine kinases or associated SH2-containing proteins play a crucial
role.
Volume 271,
Number 10,
Issue of March 8, 1996 pp. 5680-5685
©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES
YQP
) in the C-terminal regulatory domain
of c-Src, and its binding was hindered by phosphorylation of this
tyrosine as determined by peptide competition assay. Combined
immunoprecipitation/Western blotting revealed that clone 28 reacted
with a 60-kDa protein that was precipitated by mAb 327, a well known
monoclonal antibody against v-Src and c-Src. Cyanogen bromide cleavage
and two-dimensional tryptic maps confirmed that clone 28 was specific
for the active form (Tyr-530 not phosphorylated), whereas mAb 327
recognized the inactive form (Tyr-530 phosphorylated) as well as the
active form. Clone 28 selectively immunoprecipitated the active form
and augmented its kinase activity. Preabsorption experiments revealed
that clone 28 could not completely immunoprecipitate the mAb 327
binding 60-kDa protein in either an in vitro or an in vivo phosphorylation system. These observations, taken together,
strongly suggest the existence of multiple forms of c-Src as proposed
by Cooper and Howell(1993) (Cooper, J. A., and Howell, B.(1993) Cell 73, 1051-1054).
)3 domain, an SH2 domain, a kinase domain, and a C-terminal
regulatory domain (for reviews, see Margolis(1992), Pawson and
Gish(1992), Cooper and Howell(1993), and Erpel and Courtneidge(1995)).
Production of mAbs
A peptide corresponding to
the C-terminal region of human c-Src (LEDYFTSTEPQYQPGENL, residues
519-536) was synthesized and coupled to keyhole limpet hemocyanin
(Calbiochem) with the bifunctional coupling reagent sulfosuccinimidyl
4-(N-maleimidomethyl)cyclohexane-1-carboxylate (Pierce). This
conjugate was used for mouse immunization as described by Harlow and
Lane(1988). The hybridomas obtained were screened by means of
enzyme-linked immunosorbent assay with a synthetic peptide as the
antigen, and by Western blotting or immunoprecipitation using human
cell line lysates.Preparation of Lysates from Human
Platelets
Freshly collected human blood was centrifuged at 1000
rpm for 10 min in the presence of sodium citrate as an anticoagulant.
The supernatant was collected and centrifuged again at 3000 rpm for 10
min. The platelets, enriched in the pellet, were disrupted in
phosphate-buffered saline (PBS(-)) containing 1% (w/v) Nonidet
P-40, 20 mM NaF, 2 mM orthovanadate, 5 µg/ml
leupeptin, and 0.25 mM (p-amidinophenyl)methanesulfonyl fluoride) in a Teflon
homogenizer. The homogenate was centrifuged at 100,000 
g for 30 min and the supernatant was used for further analysis.
Protein concentrations were determined by means of the bicinchoninic
acid (BCA) assay (Pierce).Western Blotting
After SDS-polyacrylamide gel
electrophoresis, proteins were transferred to a nylon membrane
(Millipore, polyvinylidene difluoride, IPVH 000-10) by means of a
semidry blotting system (Pharmacia Biotech Inc.) at a constant current
of 0.8 mA/cm
. Blocking was performed for 1 h in a
Tris-buffered solution containing 2% (w/v) skim milk (Difco). After
incubation with either clone 28 or mAb 327 (Lipsich et al.,
1983; Oncogene Science Inc., OP-07L), then with peroxidase-conjugated
sheep anti-mouse immunoglobulin (Amersham Corp.), and the stain was
developed with the Konica immunostain kit using 4-chloronaphthol as the
substrate.In Vitro and in Vivo Phosphorylation Assays
For in vitro phosphorylation, human platelets were disrupted with
RIPA buffer without SDS (50 mM Tris-HCl, pH 8.2, containing
150 mM NaCl, 20 mM NaF, 10 mM EDTA, 2 mM orthovanadate, 1% (w/v) Triton X-100, 1% (w/v) sodium
deoxycholate, 5 µg/ml leupeptin, and 0.25 mM (p-amidinophenyl)methanesulfonyl fluoride) and treated
with mAbs. In each experiment, we confirmed by titration that the
amount of antibody used was sufficient to precipitate all of the
available protein. Immune complexes were precipitated with protein
A-Sepharose CL-4B (Zymed) or anti-mouse IgG-agarose (American Corlex).
After washing the precipitate three times with RIPA buffer without SDS,
then twice with phosphorylation buffer (20 mM HEPES, pH 7.5,
containing 150 mM NaCl and 5 mM MnCl), we
added [-
P]ATP (37 kBq (1 µCi); Amersham
PB170) to the immune complex. For in vivo phosphorylation,
human platelets were metabolically labeled with
[
P]PO
(3.7 MBq
(0.1 mCi)/ml; Amersham PBS11) for 2 h. Immunoprecipitation was done by
the same procedure used for in vitro phosphorylation, except
that the RIPA buffer used for washing contained 0.1% (w/v) SDS. Peptide
competition and preabsorption experiments were performed in these
systems.
Phosphopeptide Mapping
Phosphorylated 60-kDa bands
were excised from the dried gels and rehydrated with a solution
containing 125 mM Tris-HCl, pH 6.8, 0.1% (w/v) SDS, and 1
mM EDTA. The bands were partially digested with V8 protease in
the SDS-polyacrylamide gel as described by Cleveland et
al.(1977). Cyanogen bromide mapping was performed according to
Pepinsky(1983). For two-dimensional tryptic mapping, V1 and V2 bands
were excised from gels and rehydrated with several changes of 20% (v/v)
isopropanol and then 100% methanol. After complete drying, gel bands
were digested with trypsin treated with tosylphenylalanyl chloromethyl
ketone (50 µg/ml in 50 mM ammonium bicarbonate, pH 8.5) at
37 °C overnight. Clarified supernatants of these digests were dried
down in a Speed-Vac concentrator (Savant) and washed with water by
three cycles of suspension and vacuum drying. Finally, samples were
resuspended in 10 µl of electrophoresis solvent (acetic acid:formic
acid:HO = 15:5:80) and spotted on TLC plates (silica
gel 60; Merck). Tryptic peptides were first subjected to
electrophoresis in the above solvent, then to chromatography in the
second dimension in a different solvent (n-butanol:pyridine:acetic acid:HO =
65:50:10:40). Phosphopeptide maps were visualized by means of a Fujix
BAS2000 Bio-Image Analyzer (Itohara et al., 1993).Immunofluorescence Microscopy
Immunofluorescence
microscopy was performed as described by Sakai et al.(1995),
with a slight modification. Briefly, rat normal (immortalized) cell
line 3Y1 was fixed in 3.5% (w/v) paraformaldehyde in 0.1 M cacodylate buffer (pH 7.4) containing 2 mM sodium
orthovanadate for 20 min at 4 °C and washed with Tris-buffered
saline (TBS). Cells were then permeabilized by treatment with 0.2%
(v/v) Triton X-100 in TBS containing 2 mM sodium orthovanadate
for 15 min at 4 °C. They were washed with TBS containing 0.5 mM sodium orthovanadate and incubated in TBS containing 1% (w/v)
bovine serum albumin for 30 min to block nonspcific protein binding.
Slides were then incubated with primary monoclonal antibodies for 60
min at room temperature (normal mouse IgG was used as a negative
control antibody). The slides were washed with TBS containing 0.5
mM sodium orthovanadate and were treated with
fluorescein-labeled, affinity-purified goat anti-mouse IgG (MBL,
Nagoya, Japan) for 40 min at room temperature. Slides were briefly
washed with TBS, mounted with glass coverslips, and viewed with a BX60
fluorescence microscope (Olympus Optical Co., Ltd., Tokyo, Japan).Immunocytochemistry
Immunocytochemical
observations were performed as described by Sakai et al.(1993)
with a slight modification. Deparaffinized sections were immersed in
methanol containing 0.3% (v/v) hydrogen peroxide to inactivate
endogenous peroxidases. After washing with PBS(-), the sections
were incubated in PBS containing 5% (v/v) normal goat serum to block
nonspecific protein binding, then pretreated with a biotin/avidin
blocking kit (Vector Laboratories Inc.) to block avidin binding to
endogenous biotin. They were then treated with antibodies and left
overnight at 4 °C (normal mouse IgG was used as a negative control
primary antibody). The sections were treated with a secondary antibody,
biotinylated goat anti-mouse IgG (Organon Teknika), and then with
peroxidase-conjugated streptavidin (Histofine, Nichirei Corp.). The
color was developed with a freshly prepared chromogen solution
containing 0.1% (w/v) 3,3`-diaminobenzidine tetrahydrochloride (Dojindo
Laboratories) and 0.02% (v/v) hydrogen peroxide in 50 mM Tris-HCl, pH 7.6. Sections were counterstained with hematoxylin,
mounted with glass coverslips, and observed under a New Vanox-s
microscope (Olympus Optical Co., Ltd.).
Clone 28 Detected a 60-kDa Protein Recognized by mAb
327
Of five hybridomas screened by means of an enzyme-linked
immunosorbent assay system with the peptide that was used for
immunization (LEDYFTSTPQYQPGENL, amino acids 519-536 in human
c-Src), one clone, termed clone 28, was sensitive enough to detect a
60-kDa band in a human platelet lysate by Western blotting (Fig. 1A, lane 2). By combined
immunoprecipitation/Western blotting, this 60-kDa protein was
recognized by mAb 327 (Fig. 1B, lane 2), whose
epitope is thought to be in the SH3 domain of v-Src and c-Src. The
60-kDa protein in the immunoprecipitate of clone 28 was still
recognized by clone 28 in the above system, demonstrating that clone 28
retains its specificity even when the c-Src protein is denatured (Fig. 1B, lane 3).
Clone 28 Sensitively Detected the Active Form of
c-Src
Clone 28 immunoprecipitated phosphorylated 60-kDa protein
from lysates of human platelets metabolically labeled with
[P]PO
(Fig. 2A). The detection sensitivity of clone 28
was comparable to that of mAb 327 as determined by titration of each
antibody. In contrast to this in vivo phosphorylation, only
the clone 28 precipitate displayed strong in vitro phosphorylation. A human platelet lysate was subjected to
immunoprecipitation by either clone 28 or mAb 327. After a thorough
wash with RIPA buffer without SDS, and then with phosphorylation
buffer, [
-
P]ATP was added for in vitro phosphorylation. The fluorograph obtained (Fig. 2B) showed that the clone 28 precipitate was
heavily phosphorylated compared with the mAb 327 precipitate. As
determined by titration of the antibody concentration, the clone 28
precipitate underwent 50 times as much autophosphorylation as did the
mAb 327 precipitate. Taken together, these results show clone 28 to be
a sensitive and selective detector of the activated form of c-Src
(Tyr-530 not phosphorylated). Augmentation of the kinase activity was
confirmed by mixing clone 28 and purified c-Src in the in vitro phosphorylation system (data not shown).
P]PO
, then
immunoprecipitated with control mouse IgG (lane 1, 10 µg),
clone 28 (lane 2, 10 µg; lane 3, 1 µg; lane 4, 0.1 µg), or mAb 327 (lane 5, 10 µg; lane 6, 1 µg; lane 7, 0.1 µg). B, in vitro phosphorylation assay. In vitro kinase
activity was assessed in human platelet lysates immunoprecipitated by
control mouse IgG (lane 1, 10 µg), clone 28 (lane
2, 10 µg; lane 3, 1 µg; lane 4, 0.1
µg), or mAb 327 (lane 5, 10 µg; lane 6, 1
µg; lane 7, 0.1 µg).
The Epitope of Clone 28 Was Assigned to a Region Adjacent
to the C-terminal Tyrosine Residue of c-Src
In order to define
the site within the C-terminal region of c-Src to which clone 28 binds,
we synthesized a series of peptides corresponding to segments of the
peptide used for immunization (Table 1). The in vitro phosphorylation assay was used to detect competition by each
peptide for clone 28 (Fig. 3A). Antigen recognition was
completely inhibited by the peptides QYQPGENL (amino acids
529-536), QFQPGENL (amino acids 529-536, Tyr 530 replaced
by Phe) and QYQPGDQT (amino acids 529-536, ENL replaced by DQT,
identical to the corresponding region in c-Fgr), and partially
inhibited by EPQYQPG (amino acids 527-533), all at a
concentration of 100 µg/ml. The N-terminal eight amino acids of the
peptide used for immunization, LEDYFTST (amino acids 519-526),
did not influence antigen recognition. We therefore concluded that
clone 28 bound to the C-terminal region of c-Src in the vicinity of
Tyr-530. For further confirmation of the specificity of this clone, we
used the peptide QYQPGENL in either the nonphosphorylated or the
phosphorylated form for in vitro phosphorylation. Whereas the
nonphosphorylated peptide completely inhibited antigen recognition even
at the lowest concentration used (1 µg/ml; Fig. 3B, lanes 2-4), the phosphorylated peptide only partially
inhibited the phosphorylation (27% at 1 µg/ml and 88% at 10
µg/ml; Fig. 3B, lanes 5-7). Thus we
could localize the epitope to the center of critical C-terminal
regulatory domain.
Comparison of Phosphorylation State of the
Immunoprecipitates by Peptide Mapping and Preabsorption
For the
further analysis of the phosphorylation state of c-Src recognized by
clone 28 or mAb 327, each 60-kDa band was excised from the gel shown in Fig. 2A and subjected to partial digestion by V8
protease (Fig. 4A). The phosphorylation of both the V1
fragment (which contains phosphorylated Ser-12, Ser-17, Thr-34, and
Thr-46 in c-Src; Courtneidge and Smith(1984)) and the V2 fragment
(which contains phosphorylated Tyr-419 and Tyr-530 in c-Src) was
observed in both precipitates by this mapping procedure. Cyanogen
bromide cleavage confirmed this result and also showed that Tyr-530 was
phosphorylated only in the mAb 327 precipitate (Fig. 4B). Tryptic maps of V2 fragments derived from
clone 28 and mAb 327 precipitates also confirmed this result;
additional spots not seen in the clone 28 precipitate were detected in
the mAb 327 precipitate (Fig. 4C, c and d), whereas tryptic maps of V1 fragments from both
precipitates displayed almost identical patterns (Fig. 4C, a and b).
P]PO
were
pretreated with normal mouse IgG or clone 28, then subjected to clone
28 and mAb 327 precipitation (Fig. 5A). Lanes 1 and 2 show the basal level of clone 28 and mAb 327
binding activity toward the phosphorylated 60-kDa form when normal
mouse IgG was used in preabsorption step. Even when excess clone 28 was
used in the preabsorption step, substantial phosphorylated 60-kDa bands
remained that were recognized by mAb 327 (lane 3). This result
suggested that substantial amounts of c-Src were phosphorylated at
Tyr-530 in human platelets. (If a significant amount of the observed
phosphorylation were due to Ser or Thr, we would have expected a
reduction in the intensity of the 60-kDa band (see Fig. 4A).) In addition, we pretreated cold platelet
lysates with normal mouse IgG or clone 28 and then subjected them to
clone 28 and mAb 327 precipitation (Fig. 5B). Under
conditions when both clone 28 and mAb 327 showed high
autophosphorylation activity (lanes 1 and 2),
substantial kinase activity was observed in the mAb 327 precipitate
even when excess clone 28 was used in the preabsorption step (lane
3).
Immunocytochemical Localization of the Active Form of
c-Src Tyrosine Kinase
We examined the cellular distribution of
the active form of c-Src tyrosine kinase in normal rat 3Y1 cells. In
addition to the expected submembranous localization, we also observed
intense staining on the outer nuclear membrane and the cytoskeletal
components (Fig. 6A). In contrast to clone 28, the
staining with mAb 327 was too weak to show any distinct localization
within the cell (Fig. 6B).
)
))
We thank G. E. Smyth for critical reading of this
manuscript and M. Todoroki for outstanding photographic assistance.
©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
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 J. R. Slupsky, A. S. Kamiguti, R. J. Harris, J. C. Cawley, and M. Zuzel Central Role of Protein Kinase C{epsilon} in Constitutive Activation of ERK1/2 and Rac1 in the Malignant Cells of Hairy Cell Leukemia Am. J. Pathol., February 1, 2007; 170(2): 745 - 754. [Abstract] [Full Text] [PDF]
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 J. Mojsilovic-Petrovic, G.-B. Jeong, A. Crocker, A. Arneja, S. David, D. Russell, and R. G. Kalb Protecting Motor Neurons from Toxic Insult by Antagonism of Adenosine A2a and Trk Receptors J. Neurosci., September 6, 2006; 26(36): 9250 - 9263. [Abstract] [Full Text] [PDF]
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 T. Iwasaki, K.-i. Sato, K.-i. Yoshino, S. Itakura, K. Kosuge, A. A. Tokmakov, K. Owada, K. Yonezawa, and Y. Fukami Phylogeny of Vertebrate Src Tyrosine Kinases Revealed by the Epitope Region of mAb327. J. Biochem., March 1, 2006; 139(3): 347 - 354. [Abstract] [Full Text] [PDF]
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 A. Shimizu, T. Maruyama, K. Tamaki, H. Uchida, H. Asada, and Y. Yoshimura Impairment of Decidualization in SRC-Deficient Mice Biol Reprod, December 1, 2005; 73(6): 1219 - 1227. [Abstract] [Full Text] [PDF]
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 T. Kurita, R. T. Medina, A. A. Mills, and G. R. Cunha Role of p63 and basal cells in the prostate Development, October 15, 2004; 131(20): 4955 - 4964. [Abstract] [Full Text] [PDF]
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B. Knoll and U. Drescher Src Family Kinases Are Involved in EphA Receptor-Mediated Retinal Axon Guidance J. Neurosci., July 14, 2004; 24(28): 6248 - 6257. [Abstract] [Full Text] [PDF]
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 J. R. Tejedo, G. M. Cahuana, R. Ramirez, M. Esbert, J. Jimenez, F. Sobrino, and F. J. Bedoya Nitric Oxide Triggers the Phosphatidylinositol 3-Kinase/Akt Survival Pathway in Insulin-Producing RINm5F Cells by Arousing Src to Activate Insulin Receptor Substrate-1 Endocrinology, May 1, 2004; 145(5): 2319 - 2327. [Abstract] [Full Text] [PDF]
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T. Maruyama, Y. Yamamoto, A. Shimizu, H. Masuda, N. Sakai, R. Sakurai, H. Asada, and Y. Yoshimura Pyrazolo Pyrimidine-Type Inhibitors of Src Family Tyrosine Kinases Promote Ovarian Steroid-Induced Differentiation of Human Endometrial Stromal Cells In Vitro Biol Reprod, January 1, 2004; 70(1): 214 - 221. [Abstract] [Full Text] [PDF]
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X. Li, Y. Yang, Y. Hu, D. Dang, J. Regezi, B. L. Schmidt, A. Atakilit, B. Chen, D. Ellis, and D. M. Ramos {alpha}v{beta}6-Fyn Signaling Promotes Oral Cancer Progression J. Biol. Chem., October 24, 2003; 278(43): 41646 - 41653. [Abstract] [Full Text] [PDF]
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 N. Lerner-Marmarosh, M. Yoshizumi, W. Che, J. Surapisitchat, H. Kawakatsu, M. Akaike, B. Ding, Q. Huang, C. Yan, B. C. Berk, et al. Inhibition of Tumor Necrosis Factor-{alpha}-Induced SHP-2 Phosphatase Activity by Shear Stress: A Mechanism to Reduce Endothelial Inflammation Arterioscler. Thromb. Vasc. Biol., October 1, 2003; 23(10): 1775 - 1781. [Abstract] [Full Text] [PDF]
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M. Takikita-Suzuki, M. Haneda, M. Sasahara, M. K. Owada, T. Nakagawa, M. Isono, S. Takikita, D. Koya, K. Ogasawara, and R. Kikkawa Activation of Src Kinase in Platelet-Derived Growth Factor-B-Dependent Tubular Regeneration after Acute Ischemic Renal Injury Am. J. Pathol., July 1, 2003; 163(1): 277 - 286. [Abstract] [Full Text] [PDF]
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J. Cottom, L. M. Salvador, E. T. Maizels, S. Reierstad, Y. Park, D. W. Carr, M. A. Davare, J. W. Hell, S. S. Palmer, P. Dent, et al. Follicle-stimulating Hormone Activates Extracellular Signal-regulated Kinase but Not Extracellular Signal-regulated Kinase Kinase through a 100-kDa Phosphotyrosine Phosphatase J. Biol. Chem., February 21, 2003; 278(9): 7167 - 7179. [Abstract] [Full Text] [PDF]
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 Y. Yamamoto, T. Maruyama, N. Sakai, R. Sakurai, A. Shimizu, T. Hamatani, H. Masuda, H. Uchida, H. Sabe, and Y. Yoshimura Expression and subcellular distribution of the active form of c-Src tyrosine kinase in differentiating human endometrial stromal cells Mol. Hum. Reprod., December 1, 2002; 8(12): 1117 - 1124. [Abstract] [Full Text] [PDF]
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K.-i. Sato, T. Nagao, M. Kakumoto, M. Kimoto, T. Otsuki, T. Iwasaki, A. A. Tokmakov, K. Owada, and Y. Fukami Adaptor Protein Shc Is an Isoform-specific Direct Activator of the Tyrosine Kinase c-Src J. Biol. Chem., August 9, 2002; 277(33): 29568 - 29576. [Abstract] [Full Text] [PDF]
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 L. A. Cary, R. A. Klinghoffer, C. Sachsenmaier, and J. A. Cooper Src Catalytic but Not Scaffolding Function Is Needed for Integrin-Regulated Tyrosine Phosphorylation, Cell Migration, and Cell Spreading Mol. Cell. Biol., April 15, 2002; 22(8): 2427 - 2440. [Abstract] [Full Text] [PDF]
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 X. Li, J. Regezi, F. P. Ross, S. Blystone, D. Ilic, S. P. L. Leong, and D. M. Ramos Integrin {alpha}v{beta}3 mediates K1735 murine melanoma cell motility in vivo and in vitro J. Cell Sci., March 9, 2002; 114(14): 2665 - 2672. [Abstract] [Full Text] [PDF]
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L. Li, M. Okura, and A. Imamoto Focal Adhesions Require Catalytic Activity of Src Family Kinases To Mediate Integrin-Matrix Adhesion Mol. Cell. Biol., February 15, 2002; 22(4): 1203 - 1217. [Abstract] [Full Text] [PDF]
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S. Satoh and T. Tominaga mDia-interacting Protein Acts Downstream of Rho-mDia and Modifies Src Activation and Stress Fiber Formation J. Biol. Chem., October 12, 2001; 276(42): 39290 - 39294. [Abstract] [Full Text] [PDF]
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 E. G. Araujo, C. Bianchi, K. Sato, R. Faro, X. A. Li, and F. W. Sellke Inactivation of the MEK/ERK pathway in the myocardium during cardiopulmonary bypass J. Thorac. Cardiovasc. Surg., April 1, 2001; 121(4): 773 - 781. [Abstract] [Full Text] [PDF]
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