Previous Article | Next Article 
Molecular and Cellular Biology, May 2000, p. 3576-3589, Vol. 20, No. 10
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Essential Role for the C-Terminal Noncatalytic
Region of SHIP in Fc
RIIB1-Mediated Inhibitory Signaling
M. Javad
Aman,
Scott F.
Walk,
Michael E.
March,
Hua-Poo
Su,
D. Jeannean
Carver, and
Kodimangalam S.
Ravichandran*
Beirne B. Carter Center for Immunology
Research and the Department of Microbiology, University of Virginia,
Charlottesville, Virginia 22908
Received 2 December 1999/Returned for modification 20 January
2000/Accepted 15 February 2000
 |
ABSTRACT |
The inositol phosphatase SHIP binds to the Fc
RIIB1 receptor and
plays a critical role in FcRIIB1-mediated inhibition of B-cell
proliferation and immunoglobulin synthesis. The molecular details of
SHIP function are not fully understood. While point mutations of the
signature motifs in the inositol phosphatase domain abolish SHIP's
ability to inhibit calcium flux in B cells, little is known about the
function of the evolutionarily conserved, putative noncatalytic regions
of SHIP in vivo. In this study, through a systematic mutagenesis
approach, we identified the inositol phosphatase domain of SHIP between
amino acids 400 and 866. Through reconstitution of a SHIP-deficient
B-cell line with wild-type and mutant forms of SHIP, we demonstrate
that the catalytic domain alone is not sufficient to mediate
FcRIIB1/SHIP-dependent inhibition of B-cell receptor signaling.
Expression of a truncation mutant of SHIP that has intact phosphatase
activity but lacks the last 190 amino acids showed that the
noncatalytic region in the C terminus is essential for inhibitory
signaling. Mutation of two tyrosines within this C-terminal region,
previously identified as important in binding to Shc, showed a reduced
inhibition of calcium flux. However, studies with an Shc-deficient
B-cell line indicated that Shc-SHIP complex formation is not required
and that other proteins that bind these tyrosines may be important in
FcRIIB1/SHIP-mediated calcium inhibition. Interestingly, membrane
targeting of SHIP lacking the C terminus is able to restore this
inhibition, suggesting a role for the C terminus in localization or
stabilization of SHIP interaction at the membrane. Taken together,
these data suggest that the noncatalytic carboxyl-terminal 190 amino
acids of SHIP play a critical role in SHIP function in B cells and may
play a similar role in several other receptor systems where SHIP
functions as a negative regulator.
| |
INTRODUCTION |
B-cell immune response to antigens
is terminated or attenuated by surface receptors such as FcRIIB1 and
CD22 on B cells (5, 11, 34, 48). These inhibitory receptors
recruit specific intracellular signaling proteins, which play a key
role in attenuating the early activation events initiated by
cross-linking of the B-cell receptor (BCR). FcRIIB1 is an important
mediator of the attenuation of B-cell activation by antibody-antigen
immune complexes in the later phases of the immune response
(49). Coengagement of FcRIIB1 with BCR results in a
potent inhibitory signal that depends on the recruitment of Src
homology 2-containing inositol phosphatase (SHIP). SHIP binds to the
phosphorylated immunotyrosine-based motif (ITIM) in the cytoplasmic
region of FcRIIB1 (43, 44), and SHIP-mediated
dephosphorylation of specific phosphoinositide products has been
implicated in terminating the BCR-induced activation events (4,
14, 53).
SHIP was initially characterized in hematopoietic cells as a 145-kDa
phosphoprotein that coprecipitated with the adapter protein Shc upon
stimulation of specific receptors (6-8, 37, 50, 52, 54).
Molecular cloning of SHIP identified it as a 5'-inositolphosphatase (5'-IPase), based on homology with other 5'-IPases (9, 13, 29, 36,
45, 57). SHIP specifically dephosphorylates
phosphatidylinositol-3,4,5-trisphosphate (PIP3), a major product of
phosphoinositide-3-kinase (PI3K) enzymatic action, as well as
inositoltetrakisphosphate (IP4), both in vitro (28, 36) and
in vivo (53). The requirement for SHIP in
FcRIIB1-mediated inhibition of BCR signaling has been well
established (4, 5, 14, 20, 32, 44, 48, 53). Recruitment of
enzymatically active SHIP to the receptor complex results in potent
inhibition of intracellular calcium flux (12, 30, 44),
diminished activation of the serine-threonine kinase Akt (1, 3,
17, 27), inhibition of the Ras/mitogen-activated protein kinase
pathway (56), and the regulation of apoptosis (2, 38,
47). Further evidence for a crucial role for SHIP in negative
regulation of BCR signaling comes from studies with SHIP knockout mice
as well as SHIP
/ Rag/ chimeric mice, in
which BCR-mediated responses are heightened and the
FcRIIB1-dependent inhibition of BCR responses is abolished (23,
39).
It is noteworthy that SHIP also negatively regulates histamine release
in response to engagement of the immunoglobulin E (IgE) receptor and
Steel factor (25, 26, 43), as well as the proliferative response to interleukin-3 and the macrophage colony-stimulating factor
(36). Ex vivo studies with cells from SHIP-deficient mice
have suggested that in the absence of SHIP, the myeloid progenitor cells hyperproliferate in response to cytokines and hematopoietic growth factors, with the dose-response curve being left-shifted (23). Taken together, these studies have clearly established a functional role for SHIP as a negative regulator of cytokine and
antigen receptor signaling.
The 145-kDa isoform of SHIP, the predominant form expressed in
hematopoietic cells, is composed of an N-terminal Src homology 2 (SH2)
domain, a central, loosely defined IPase domain, and a C-terminal
region which contains multiple motifs involved in protein-protein interactions (9, 13, 29, 36, 45, 57). While mutation of
residues within the signature motifs of the IPase abolishes SHIP's
ability to inhibit calcium flux (44), little is known about
the function of noncatalytic regions of SHIP in vivo. Interestingly, multiple isoforms and cleavage products of SHIP have been detected in
hematopoietic cells and have been proposed to perform specific functions (10, 15, 41). Since the putative catalytic domain of SHIP is left intact in the various isoforms, the regions outside of
the catalytic domain, through interaction with other proteins, are
likely to play a key role in determining SHIP function under different
conditions. Thus, defining the precise boundaries of the phosphatase
domain of SHIP, identifying the proteins that bind to the noncatalytic
regions, and determining how they regulate SHIP function have become
important issues to be resolved.
In this study, through a systematic mutagenesis approach, we determined
that the boundaries of the IPase domain of SHIP exist between amino
acids 400 and 866. Through reconstitution of a SHIP-deficient B-cell
line with wild-type (wt) and mutant forms of SHIP, we demonstrate that
the catalytic domain alone is not sufficient and that the C-terminal
noncatalytic region is essential for FcRIIB1/SHIP-mediated inhibitory signaling. Our data also suggest that the C-terminal region
of SHIP may play a key role in the localization of SHIP to the membrane
during inhibitory signaling.
| |
MATERIALS AND METHODS |
Plasmids.
The original murine SHIP cDNA was kindly provided
by Gerald Krystal (Terry Fox Labs, Vancouver, Canada). Plasmids
encoding glutathione-S-transferase (GST)-tagged SHIP were
generated by cloning the wt and mutant constructs in-frame into the
pEBG vector as described previously (33). SHIP versions
tagged with three copies of hemagglutinin (HA) were generated in the
pEBB vector as described before (33) and subcloned into the
pApuro vector (55). Both the pEBG and pEBB vectors regulate
protein expression under the elongation factor-1 (EF-1) promoter, while
the pApuro vector expresses proteins under the chicken actin promoter.
The constructs encoding partial regions of SHIP were generated by PCR
and/or subcloning of the appropriate regions into the pEBG or pEBB
vector. All PCR-generated products were sequenced to ensure fidelity.
The plasmids encoding SHIP-SH2 fused to the linker were generated in
the pApuro vector. The 18-amino-acid linker was designed based on the
description of Pantoliano et al. (46). An enzymatically inactive form of SHIP was generated by incorporating three point mutations, P671A, D675A, and R676G, into the IPase signature motif as
described previously (44). The plasmid encoding FcRIIB1 in pApuro was kindly provided by Tomo Kurosaki (Osaka, Japan). FcRIIB1 was also subcloned into the pEFneo vector, which drives expression under the EF-1 promoter. For generation of Fc receptor (FcR)-SHIP chimeric proteins, the insert encoding SHIPwt or
SHIP1-900 was fused in-frame to a truncated FcRIIB1
(Fc; truncated at residue 300 in its cytoplasmic tail and thus lacking
the ITIM motif that normally binds SHIP) in the pApuro vector.
Cell lines, antibodies, and reagents.
The SHIP-deficient and
wt DT40 cell lines were obtained from Tomo Kurosaki. These cells were
grown in RPMI-1640 medium supplemented with 10% fetal bovine serum,
1% chicken serum (Sigma Biochemicals, St. Louis, Mo.), penicillin,
streptomycin, 2 mM L-glutamine, and 50 µM
2-mercaptoethanol. Murine A20 cells were cultured in RPMI-1640 medium
supplemented with 10% fetal bovine serum, penicillin, streptomycin, 2 mM L-glutamine, and 20 µM 2-mercaptoethanol. 293T cells
were maintained in Dulbecco's modified Eagle's medium supplemented with 10% fetal calf serum, 2 mM L-glutamine, and
antibiotics. Rabbit anti-mouse IgG [F(ab')2 fragment and
intact antibody] was purchased from Jackson ImmunoResearch
Laboratories (West Grove, Pa.). Murine monoclonal anti-chicken IgM (M4)
antibody was obtained from Southern Biotechnology Associates
(Birmingham, Ala.). Polyclonal and monoclonal anti-Shc antibodies and
the horseradish peroxidase-conjugated antiphosphotyrosine RC20 antibody
were purchased from Transduction Laboratories. Rabbit anti-SHIP
antiserum was a generous gift from G. Krystal. Purified, constitutively
active PI3K (P110*) was kindly provided by A. Klippel (Chiron
Corporation, Emeryville, Calif.).
Transfections.
293T cells were transfected by the calcium
phosphate precipitation method with reagents from 5' 
3' Inc.
according to manufacturer's instructions. DT40 cells were transfected
with 20 µg of linearized plasmid DNA (pApuro for SHIP constructs or
pEFneo for FcRIIB1) by electroporation at 250 V and 960 µF. Cells
were cultured for 24 h before selection in medium containing
puromycin (0.5 µg/ml) or G418 (2.0 mg/ml) in 96-well plates. DT40
lines expressing FcRIIB1 were screened with the 2.4G2 antibody and
by flow cytometry (see below). A representative FcRIIB1-positive
clone was used for transfection of plasmids encoding the various SHIP
constructs. The clones expressing HA-SHIP were identified by Western
blot with anti-HA antibody.
Stimulation, immunoprecipitations, and immunoblotting.
Stimulation of DT40 cells was performed as previously described
(44). Briefly, cells were preincubated at 37°C with either 3 µg of F(ab')2 fragment of rabbit anti-mouse IgM per ml
for BCR stimulation or 6 µg of an intact form of the same antibody
per ml for BCR plus FcR cross-linking. Stimulation was initiated by adding 1 µg of mouse anti-chicken IgM (M4) per ml. For Western blotting and immunoprecipitation, cells were lysed in lysis buffer containing 50 mM Tris (pH 7.6); 150 mM NaCl; 1% NP-40; 10 mM sodium pyrophosphate; 10 µg/ml each of aprotinin, leupeptin, and pepstatin; 10mM NaF; 1 mM NaVO4; and 2 mM phenylmethylsulfonyl
fluoride. Cellular debris was cleared by centrifugation, and proteins
were precipitated from lysates with either glutathione-Sepharose beads or the relevant antibody plus protein A-conjugated beads. Beads were
washed four times with lysis buffer, and bound proteins were analyzed
by standard sodium dodecyl sulfate-polyacrylamide gel electrophoresis
and developed by enhanced chemiluminescence.
IPase assays.
32P-labeled PIP3 was generated by
using a constitutively active form of PI3K (p110*) (31). A
mixture of 12.5 nmol of phosphatidylinositol-(4,5)-bisphosphate (PIP2)
and 185 nmol of phosphatidylserine were sonicated in 10 mM HEPES (pH
7)-1 mM EGTA to generate micelles and incubated in 500 µl of a
kinase buffer consisting of 0.2 mM ATP, 5 mM MgCl2, 30 mM
HEPES (pH 7), 5 µM EGTA, 150 µCi of [32P]ATP, and
5 µg of p110* for 30 min at room temperature. The reaction was
terminated by addition of EDTA, and lipids were extracted in 800 µl
of chloroform-methanol (1:1) and 125 µl of 5 M HCl. After drying the
organic phase, the lipids were resuspended in 50 mM Tris (pH
7.5)-0.125% NP-40 by sonication and used as the substrate for the
phosphatase assays. Phosphatase assays were performed for 30 min to
1 h at 37°C after adding 100 µl of the substrate solution and
50 µl of 50 mM Tris (pH 7.5)-30 mM MgCl2 to
immunoprecipitated enzyme equilibrated in Tris-MgCl2
buffer. The lipids were extracted as above and analyzed on thin-layer chromatography plates activated in potassium oxalate-methanol as
described before (36). The phosphatase activity of SHIP
toward IP4 was assayed with 3H-labeled IP4 (NEN Dupont).
Immunoprecipitated SHIP and SHIP mutants were washed in 50 mM MES
(2-N-morpholinoethanesulfonic acid)-3 mM MgCl2
and incubated for 30 min at 37°C in the same buffer supplemented with
10 µM unlabeled IP4 (a generous gift from G Prestwich, University of
Utah) and 25 nM (0.05 µCi/100 µl) [3H]IP4. The
reaction was stopped by adding 1 ml of cold water and analyzed by fast
protein liquid chromatography (FPLC) (Pharmacia). Samples were loaded
on a strong cationic Mono Q (Pharmacia,) column and eluted on a linear
gradient of 0.3 to 0.7 M monobasic ammonium phosphate at 0.5 ml/min.
Fractions of 0.5 ml were collected, and radioactivity was counted in a
scintillation counter.
Intracellular calcium measurements.
Cells (5 × 106) were incubated in 1 µg of Indo 1 (Molecular Probes,
Eugene, Oreg.) per ml in complete medium for 20 min in a humidified
incubator at 39°C. Cells were washed in HEPES buffer (150 mM NaCl, 5 mM KCl, 1 mM each CaCl2 and MgCl2, 10 mM HEPES [pH 7.4], 0.1% glucose, and 1% fetal calf serum), resuspended in
the same buffer, and transferred to a cuvette. Secondary antibodies, 1.5 µg of F(ab')2 fragment of rabbit anti-mouse IgM per
ml (for BCR cross-linking alone) or 3 µg of intact rabbit anti-mouse
IgM per ml (for BCR plus FcR cross-linking), were added prior to
measurement. Using an SLM 8100-C spectrofluorimeter (22),
calcium flux was recorded upon excitation at 340 nm as the ratio of
fluorescence emissions at 398 and 480 nm. The background was recorded
for 20 s, followed by addition of mouse anti-chicken IgM (M4)
antibody at 1 µg/ml.
FACS analysis.
For fluorescence-activated cell sorting
(FACS), cells were incubated at 5 × 106 cells/ml in
phosphate-buffered saline (PBS) with 1 µg of 2.4G2 (anti-FcRIIB1)
antibody per ml for 20 min at 4°C. Cells were washed twice in PBS and
stained with fluorescein isothiocyanate-conjugated anti-rat IgG at 4 µg/ml for 20 min at 4°C. The cells were then washed and analyzed on
a FACSCalibur flow cytometer (Becton Dickinson, San Jose, Calif.). As a
negative control, cells were stained with fluorescein
isothiocyanate-conjugated anti-rat IgG without primary antibody.
| |
RESULTS |
Defining the minimal IPase domain of SHIP.
To gain a better
molecular understanding of SHIP function, we undertook systematic
mutagenesis to delineate the catalytic and noncatalytic regions of
SHIP. To define the boundaries of the IPase domain of SHIP, we
generated GST-tagged versions of wt SHIP and various truncation mutants
that have deletions at the amino or carboxyl terminus (schematically
shown in Fig. 1A). To test the catalytic
activity of these SHIP versions, these constructs were transiently
expressed in 293T cells, the proteins were precipitated by glutathione
beads, and the IPase activity toward radiolabeled PIP3 was measured. To
ensure that the IPase activity measured in these assays is in fact due
to SHIP and not to a coprecipitating phosphatase activity from 293T
cells, we expressed a catalytically inactive SHIP protein in which
three residues in the signature motifs highly conserved among 5'-IPases
have been mutated (see Materials and Methods) (44). No
detectable phosphatase activity was associated with this mutant (data
not shown). Varying the amount of SHIP protein or the time of
incubation with substrates revealed that in our routine 30-min assay,
most, if not all, of the substrate was
dephosphorylated (data not shown). Identical experiments with HA-tagged
versions of SHIP showed that the HA and GST tags have no influence on
the IPase activity determined in these assays (data not shown).
View larger version (3827K):
[in this window]
[in a new window]
|
FIG. 1.
Minimal phosphatase region of SHIP. (A) Schematic
diagram of the SHIP deletion and truncation mutants. All constructs
were GST tagged at the N terminus. The positions of the SH2 domain,
IPase signature motifs, and the two Shc-phosphotyrosine binding sites
are indicated. The IPase activity of each construct, based on the data
shown in panel B, is shown. (B) 293T cells were transfected with the
indicated constructs, and the expressed proteins were precipitated with
glutathione-Sepharose beads. One half of the beads were assayed for
phosphatase activity toward 32P-labeled PIP3 and analyzed
by thin-layer chromatography (upper panel). The other half was analyzed
for protein expression by immunoblotting with an anti-GST antibody
(lower panel). Sizes are shown in kilodaltons. (C) Phosphatase activity
of GST-tagged tyrosine mutants of SHIP expressed in 293T cells and
precipitated with glutathione-Sepharose beads. The lower panel shows
the immunoblot of precipitated proteins with anti-GST antibody. (D)
Phosphatase activity of wt and mutant SHIP proteins toward soluble IP4.
Proteins precipitated, after transient expression in 293T cells, were
incubated with 3H-labeled IP4, and the reaction products
were analyzed by FPLC as described in the text. Arrows indicate the
peaks for substrate (IP4) and the product
inositol-1,3,4-trisphosphate.
|
|
We then tested deletion mutants of SHIP in this assay for their
activity toward PIP3. Deletion of the SH2 domain of SHIP (construct
166-1190) had no detectable effect on the IPase activity (Fig.
1B, lane
2). Similarly, deleting much of the C terminus of SHIP
through
truncation after amino acid 933 (1-933) also did not affect
its
catalytic activity (Fig.
1B, lane 3). As would be predicted
from the
above results, a construct that expressed amino acids
166 to 933 of
SHIP was enzymatically active (Fig.
1B, lane 4).
The triple mutation
within the IPase signature motifs again completely
abolished the
activity of the 166-933 protein (Fig.
1B, lane
5).
We then tested progressive truncations from the 166-933 region to
narrow down the catalytic domain of SHIP. A mutant SHIP
truncated at
amino acid 900 still retained enzymatic activity
(Fig.
1B, lane 6).
With respect to the N terminus, sequences up
to amino acid 400 were
dispensable for in vitro activity of SHIP,
whereas loss of a short
19-amino-acid stretch between residues
401 and 419 resulted in a
completely inactive enzyme (Fig.
1B,
lanes 7 to 10). This suggested
that the N terminus of the catalytic
domain of SHIP is located between
amino acids 401 and
419.
We also tested larger deletions at the C terminus to further specify
the carboxyl-terminal end of the catalytic domain. The
mutant
containing amino acids 166-850 and truncation mutant 1-814
were both
inactive toward PIP3, suggesting that the C-terminal
end of the IPase
domain lies between residues 850 and 900 (Fig.
1B, lanes 12 and 13). It
should be noted that in some experiments,
we have detected residual
activity with the 166-850 protein (data
not shown). Interestingly,
sequence homology comparisons between
SHIP and nine other IPases showed
that significant homology starts
around amino acid 400 and ends around
amino acid 727 of SHIP.
However, as shown above, truncation at residue
814 results in
complete loss of SHIP's enzymatic activity, while
truncation at
850 severely reduced this activity. To rule out the
possibility
that the IPase domain may in fact end at residue 727 and
that
the region between residues 727 and 850 negatively influences
SHIP
enzymatic activity in an as yet undefined manner, we generated
a
construct spanning residues 401 to 727. This mutant had no catalytic
activity toward PIP3 (Fig.
1B, lane 14), suggesting that the IPase
domain of SHIP is longer than what the sequence homology with
other
5'-IPases would predict. The only other protein in the database
that
had a region similar to residues 727 to 900 was the recently
identified
SHIP homolog SHIP-2. The homology between SHIP (also
called SHIP-1) and
SHIP-2 is mainly concentrated in the residues
up to 870. In addition,
we observed that among the non-SH2-containing
5'-phosphatases,
synaptojanin shows some extended homology to
SHIP, which stops at amino
acid 866 of SHIP. We therefore generated
a construct that covered the
region between 401 and 866 and found
this to be enzymatically active,
similar to the 401-900 protein
(Fig.
1B, lanes 15 and 16). A
bacterially expressed 401-866 protein
also had full catalytic activity
(data not shown). Kinetic studies
suggested that the 401-900 protein
was comparable to the wt SHIP
protein in dephosphorylating PIP3 (data
not shown). Taken together,
these observations narrowed the C-terminal
end of the IPase domain
to amino acid
866.
SHIP has two tyrosines in the C-terminal region that we have previously
shown to serve as Shc-phosphotyrosine binding sites
(
33). As
shown in Fig.
1C, SHIP proteins with a mutation of
either or both sites
retained enzymatic activity, suggesting that
the mutation of these two
sites per se does not affect the phosphatase
activity. However, it must
be noted that the wt SHIP expressed
in 293T cells is not phosphorylated
and hence is not associated
with Shc or other phosphotyrosine-binding
domain- or SH2-containing
proteins (data not shown). Therefore, these
data do not rule out
a possible modulation of SHIP's enzymatic
activity by molecules
that may bind to these
sites.
SHIP has also been demonstrated to have in vitro 5'-IPase activity
toward a soluble inositol substrate, IP4 (
9,
13,
29).
We
determined whether the minimal IPase domain defined above would
also
dephosphorylate IP4. The IPase activity of the above mutants
toward
3H-labeled IP4 was tested, and the reaction products were
analyzed
by FPLC with a Mono-Q column. As shown in Fig.
1D, the 401-900
protein was capable of dephosphorylating IP4 as efficiently as
the wt
SHIP, whereas the 419-933 protein was completely inactive.
This
suggested that the regions of SHIP required for dephosphorylation
of
both PIP3 and IP4 are the same or essentially
overlap.
Catalytic region of SHIP alone is not sufficient for
FcRIIB1-mediated inhibitory signaling in B cells.
It has been
demonstrated that the recruitment of SHIP (via its SH2 domain) to the
tyrosine-phosphorylated FcRIIB1 is required for inhibition of
BCR-mediated elevation of intracellular calcium (44). Since
the BCR-induced calcium flux occurs downstream of PIP3 generation and
activation of the tyrosine kinase Btk, SHIP-mediated dephosphorylation
of PIP3 and, in turn, the termination of Btk activation leading to
decreased activation of phospholipase C 2 has been recognized as the
mechanism for this inhibition (4, 14, 53). The requirement
for SHIP in FcRIIB1-mediated inhibition has been best demonstrated
in the DT40 chicken B-cell line which has been made SHIP deficient
through targeted gene disruption (20, 42, 44). To address
the requirement for the different regions of SHIP in vivo, we chose to
reconstitute this SHIP-deficient DT40 line with wt SHIP
(SHIPwt) and mutant versions of SHIP and determine the
FcRIIB1-mediated inhibition of calcium flux as a readout. We
generated stable cell lines expressing murine FcRIIB1 and either wt
or mutant SHIP proteins (see below). Multiple clones expressing each of
the transfected proteins (at least three to five clones) were routinely
analyzed. The data presented are representative of multiple experiments
performed with each of these lines.
We first tested whether the minimal phosphatase region of SHIP alone
would be sufficient for inhibition of calcium by FcR.
Since the SHIP
SH2 is required for binding to Fc
RIIB1, to examine
the effect of the
IPase domain alone in cells, we needed to provide
the SH2 domain to
this protein for targeting to the Fc
RIIB1.
To achieve this, we
generated a fusion construct in which the
SHIP SH2 domain followed by
an 18-amino-acid flexible linker (
46)
was fused to amino
acids 401 to 900 of SHIP (SH2-18aa-401-900).
As a control, the SHIP SH2
domain was fused to the rest of SHIP
through the same linker (i.e.,
full-length SHIP interrupted by
the linker; SH2-18aa-96-1190) (Fig.
2A). SHIP
/ DT40 cells
were transfected with these constructs, and multiple
clones were
selected. The expression of these mutant constructs
in two independent
clones is shown in Fig.
2B. When analyzed for
Fc
RIIB1/SHIP-dependent
inhibition of calcium flux, the minimal
region that carries the IPase
activity was unable to mediate inhibition
of BCR-induced calcium flux.
In contrast, clones expressing SH2-18aa-96-1190
showed the expected
inhibition of BCR-mediated calcium flux upon
BCR plus FcR coligation,
demonstrating no apparent defect in the
design of the fusion construct
(Fig.
2C, right panels). Consistent
with other reports, we also
observed a higher level of BCR-induced
calcium flux in SHIP-deficient
DT40 cells and those reconstituted
with nonfunctional SHIP proteins
than in DT40 cells reconstituted
with functional SHIP proteins (Fig.
2)
(see below). The above
data strongly suggested that regions other than
the catalytic
domain of SHIP are required for full inhibition of
calcium flux
through Fc
RIIB1.
View larger version (34K):
[in this window]
[in a new window]
|
FIG. 2.
Minimal phosphatase region of SHIP alone is not
sufficient for inhibition of calcium flux by FcRIIB1. (A) Schematic
diagram of the constructs designed for targeting the 401 to 900 and 96 to 1190 regions of SHIP to the FcR through fusion with the SHIP-SH2
domain via a flexible 18-amino-acid linker. (B) Expression of the
constructs depicted in panel A in SHIP/ DT40 stable
clones. Equal numbers of cells were lysed, and total lysates were
analyzed for expression of HA-tagged proteins by immunoblotting.
Molecular size markers are indicated on the left (in kilodaltons). (C)
Independent clones of SHIP/ DT40 cells stably
transfected with SH2-18aa-401-900 (left panels) or SH2-18aa-96-1190
(right panels) were loaded with indo-1 and analyzed for calcium flux as
described in Materials and Methods. Recording of the fluorescence ratio
was initiated prior to stimulation of cells with BCR cross-linking or
BCR plus FcR co-cross-linking. The arrow indicates the time of addition
of the stimulating antibody.
|
|
Sequences C-terminal to residue 900 are essential for SHIP
function.
Two noncatalytic regions, amino acids 100 to 400 between
the SH2 domain and the beginning of the IPase domain and the C-terminal region beyond residue 900, are missing from the SH2-18aa-401-900 protein. To test the role of the C-terminal region, we generated DT40
clones stably expressing a SHIP protein with the truncation at residue
900 (SHIP1-900) in SHIP/ DT40 cells.
Cross-linking of the BCR with the FcRIIB1 showed much reduced
inhibition of calcium flux in SHIP1-900-expressing cells
compared with that in cells transfected with SHIPwt (Fig. 3A).
The expression levels of both the
SHIPwt and SHIP1-900 proteins were comparable
in these clones (Fig. 3B). Surface expression of FcRIIB1 on cells
transfected with SHIP1-900 was equal to or slightly higher
than that on cells transfected with SHIPwt, ruling out
differences in FcR expression levels as a reason for diminished
inhibition by SHIP1-900 (Fig. 3C). As shown in Fig. 3D,
SHIP1-900 protein precipitated from these DT40 cells had
readily detectable in vitro enzymatic activity toward PIP3. We also
considered the possibility that SHIP1-900 may not bind FcR
as efficiently as SHIPwt, resulting in this phenotype. However, as shown in Fig. 3E, both the SHIP1-900 and
SHIPwt proteins could coprecipitate equivalent amount of
phosphorylated FcRIIB1. These data clearly demonstrated that the
C-terminal region beyond amino acid 900 is required for the efficient
function of SHIP in FcRIIB1-mediated inhibitory signaling.
View larger version (45K):
[in this window]
[in a new window]
|
FIG. 3.
C terminus of SHIP required for inhibition of calcium
flux by FcRIIB1. (A) SHIP/ DT40 cells and
transfectants expressing HA-tagged wt SHIP or SHIP truncated at amino
acid 900 (SHIP1-900) were analyzed for calcium flux upon
BCR cross-linking (heavy solid line) or BCR plus FcR co-cross-linking
(dotted line) as described in the legend to Fig. 2. (B) Expression of
SHIPwt and SHIP1-900 in the DT40 clones used
for calcium analysis in panel A was analyzed by immunoblotting. (C)
Expression of FcRIIB1 on DT40 transfectants used in the above
experiments was analyzed by flow cytometry. FcR-negative parental DT40
cells were used as a negative control (dashed line). The SHIPwt
transfectant (left panel) and the two SHIP1-900 clones
(right panel) are shown as solid lines. (D) Phosphatase activity of
SHIPwt and SHIP1-900 proteins
immunoprecipitated (IP) from DT40 clones with anti-HA antibody analyzed
with PIP3 as the substrate. The lower panel shows the immunoblot of
precipitated proteins with anti-HA antibody. Sizes are shown in
kilodaltons. (E) Coprecipitation of phosphorylated FcRIIB1 with
SHIPwt and SHIP1-900 proteins in DT40 clones.
Cells were either left unstimulated or activated by coligation with BCR
plus FcR for 5 min and lysed, and SHIP proteins were immunoprecipitated
with anti-HA antibody and analyzed by immunoblotting with
antiphosphotyrosine (pTyr) antibody (upper panel) or anti-HA
antibody (lower panel).
|
|
Tyrosines 917 and 1020 of SHIP play a role in FcRIIB1-dependent
inhibition of calcium flux.
The C-terminal region of SHIP contains
two tyrosines (Y917 and Y1020) that we have previously identified as
binding sites for the Shc-phosphotyrosine binding domain
(33). To test whether the absence of Shc binding sites may
have contributed to the diminished function of the
SHIP1-900 mutant, we transfected the SHIP-deficient DT40
cell line with a plasmid encoding full-length SHIP in which both Y917
and Y1020 have been mutated to phenylalanine
(SHIPY917F/Y1020F). We have previously demonstrated that
SHIPY917F/Y1020F fails to interact with Shc
(33). As expected, SHIPY917F/Y1020F expressed in
these DT40 clones also failed to associate with Shc upon BCR plus FcR
co-cross-linking (data not shown and Fig. 5C). We generated multiple
clones expressing different levels of SHIPY917F/Y1020F protein and analyzed those that closely matched the expression level of
SHIPwt protein. The calcium flux profile of two of the clones after BCR alone and BCR plus FcR co-cross-linking is shown in
Fig. 4A. We found that
FcRIIB1-dependent inhibition of the BCR-mediated calcium flux was
much less efficient in SHIPY917F/Y1020F-expressing cells
than in SHIPwt-reconstituted cells. This difference was most pronounced in the inhibition of sustained calcium levels (Fig.
4A). While the sustained rise in calcium levels was essentially abrogated upon BCR plus FcR co-cross-linking in
SHIPwt-expressing cells, this was not the case in
SHIPY917F/Y1020F-expressing cells. As shown in Fig. 4B and
C, the cell lines used in these experiments express comparable levels
of both SHIP proteins as well as FcRIIB1. It is noteworthy that
during the analysis of multiple clones expressing SHIPY917F/Y1020F and repeated analyses of the same clone,
we observed a greater variability in the extent of inhibition compared
with SHIP1-900. The reason for this variability is
unclear. Nevertheless, we consistently observed that the profile of the
calcium inhibition in SHIPY917F/Y1020F-expressing cells was
clearly different from that with the SHIPwt clones. These
data suggested a role for the two tyrosines and potentially for Shc
binding to these two sites as being important in SHIP-mediated
regulation of the calcium flux.
View larger version (38K):
[in this window]
[in a new window]
|
FIG. 4.
Two tyrosines in the C terminus of SHIP are required for
inhibition of calcium flux by FcRIIB1. (A) SHIP/
DT40 cells and transfectants expressing HA-tagged SHIPwt or
SHIPY917/1020F were analyzed for calcium flux upon BCR
cross-linking alone (heavy solid line) or BCR plus FcR co-cross-linking
(dotted line) as described in the legend to Fig. 2. (B) Expression of
SHIPwt and SHIPY917/1020F in the stable clones
used in panel A was determined by anti-HA immunoblotting. (C)
Expression of FcRIIB1 on DT40 transfectants used in the above
experiments was analyzed by flow cytometry with the 2.4G2 antibody.
FcR-negative parental DT40 cells were used as a negative control
(dotted line). The SHIPwt transfectants (left panel) and
SHIPY917/1020F clones (right panel) are shown as solid
lines.
|
|
The best known readout for Shc involvement in signaling has been its
tyrosine phosphorylation. We therefore determined whether
Shc
phosphorylation might be altered in cells expressing wt and
mutant
forms of SHIP. We consistently observed that the tyrosine
phosphorylation of Shc in response to BCR plus FcR coligation
is much
higher than that after BCR cross-linking alone in chicken
DT40 cells
(Fig.
5A) and the murine A20 B-cell line
(Fig.
5B),
consistent with a previous report (
30). In the
DT40 cells, BCR-induced
Shc phosphorylation is very weak (detectable
after long exposure
of the film) but is significantly enhanced by BCR
plus FcR co-cross-linking
(Fig.
5A). Interestingly, when we compared
Shc phosphorylation
after BCR plus FcR coligation in parental DT40
cells and SHIP-deficient
DT40 cells, we detected a significantly
diminished level of Shc
phosphorylation in the SHIP-deficient cells
(Fig.
5C, left panel).
When the SHIP-deficient cells were reconstituted
with SHIP
wt,
we could again detect a higher level of Shc
phosphorylation as
well as its association with SHIP in response to BCR
plus FcR
coligation (Fig.
5C, right panel). In contrast, Shc was poorly
phosphorylated in cells reconstituted with SHIP mutants that
cannot
interact with Shc, i.e., SHIP
1-900 and
SHIP
Y917F/Y1020F (Fig.
5C, right panel). These data
suggested that interaction
of Shc with SHIP is critical for efficient
tyrosine phosphorylation
of Shc.
View larger version (41K):
[in this window]
[in a new window]
|
FIG. 5.
SHIP required for maximal phosphorylation of Shc in
response to BCR plus FcR co-cross-linking. (A and B) DT40 cells (A) or
A20 cells (B) were left unstimulated or stimulated by BCR cross-linking
alone or BCR plus FcR coligation. Cells were lysed, and Shc was
immunoprecipitated (IP) with polyclonal anti-Shc antibody.
Immunoprecipitates were analyzed by immunoblotting with
antiphosphotyrosine antibody (dpTyr) (upper panels) or anti-Shc
antibody (lower panels). The p52 and p46 isoforms of Shc are indicated
by arrows. (C) Parental DT40 cells, SHIP/ DT40 cells,
or SHIP/ DT40 cells reconstituted with
SHIPwt, SHIP1-900, or
SHIPY917/1020F were left unstimulated (lanes  ) or
stimulated by BCR plus FcR co-cross-linking (lanes +), and Shc
phosphorylation was analyzed as described above. Sizes are shown in
kilodaltons.
|
|
Shc binding to SHIP is not required for FcRIIB1-mediated calcium
inhibition.
Although there is no direct evidence to date that
tyrosine phosphorylation of Shc influences calcium levels in B cells,
the above data suggested that the failure of SHIP to complex with Shc
and the subsequent failure of efficient Shc tyrosine phosphorylation may have contributed to the diminished function of the
SHIPY917F/Y1020F and SHIP1-900 proteins. To
directly test the requirement for Shc in FcRIIB1/SHIP-dependent
inhibition of BCR-induced calcium flux, we made use of a DT40 cell line
in which Shc expression has been abolished by targeted gene disruption
(21). The Shc-deficient DT40 cell line was stably
transfected with a plasmid encoding murine FcRIIB1, and multiple
clones expressing FcRIIB1 on their surface were established.
Analysis of calcium flux in these cells showed that coligation of FcR
with BCR efficiently inhibited BCR-induced calcium flux in the absence
of Shc expression. Data for two independent clones are shown in Fig.
6. In addition, we could not detect a significant difference in the enzymatic activity of Shc-bound and
Shc-free SHIP in our in vitro IPase assays with PIP3 as a substrate
(data not shown). These data suggested that Shc-SHIP complex formation
is not required for FcRIIB1-mediated inhibition of calcium flux and
that the diminished function of SHIPY917F/Y1020F may be due
to the failure of the tyrosine mutants to interact with another
molecule(s) besides Shc.
View larger version (24K):
[in this window]
[in a new window]
|
FIG. 6.
Shc not required for SHIP-mediated inhibition of calcium
flux by FcRIIB1. Shc/ DT40 cells stably transfected
with FcRIIB1 were analyzed for calcium flux upon BCR cross-linking
alone (heavy solid line) or BCR plus FcR co-cross-linking (dotted
line). Lower panels show FcRIIB1 expression in these clones analyzed
by flow cytometry.
|
|
Membrane targeting of SHIP1-900 restores inhibition of
calcium flux.
We then tested the possibility that the C terminus
of SHIP may play a role in stabilizing the membrane localization of
SHIP during FcRIIB1-mediated inhibitory signaling. We fused either SHIPwt or SHIP1-900 directly to the
cytoplasmic domain of a truncated FcRIIB1 (that lacks the ITIM motif
that would normally recruit SHIP). SHIP/ DT40 cells
were stably transfected with plasmids encoding a truncated FcRIIB1 (Fc
), Fc fused to wt SHIP (Fc-SHIPwt), or
Fc fused to SHIP1-900 (Fc-SHIP1-900). The
calcium fluxes in these cells were analyzed after BCR cross-linking
alone or BCR plus FcR cross-linking. As shown in Fig.
7, Fc-SHIP1-900 was
very efficient in inhibiting BCR-mediated calcium flux. It is
noteworthy that Fc-SHIPwt was more efficient than
Fc-SHIP1-900 in inhibiting the calcium flux. Despite this,
Fc-SHIP1-900 showed far greater inhibition than the
cytoplasmic version of SHIP1-900 (Fig. 3). This was seen
with multiple Fc-SHIP1-900-expressing clones. As
expected, the control Fc clones did not show an inhibition of calcium
flux after BCR plus FcR co-cross-linking. As shown in the bottom panel
of Fig. 7, Fc, Fc-SHIPwt, and
Fc-SHIP1-900 were expressed comparably on the cell
surface. These data suggested that membrane targeting significantly
restores SHIP1-900 function and that the C-terminal
noncatalytic region of SHIP may play a key role in stabilizing SHIP
interaction at the membrane.
View larger version (26K):
[in this window]
[in a new window]
|
FIG. 7.
Membrane-targeted SHIP1-900 can mediate
FcRIIB1-mediated calcium inhibition. SHIP/ DT40
cells were stably transfected with plasmids encoding FcRIIB1
truncated at its cytoplasmic tail (Fc), Fc fused to wt SHIP
(Fc-SHIPwt), or Fc fused to SHIP1-900)
The cells were analyzed for calcium flux after cross-linking with BCR
alone or BCR plus FcR (top panels). The increase in BCR-induced calcium
flux seen at later time points is unique to the Fc-SHIP clones, and
the reason for this is currently unclear. The surface expression of the
Fc and Fc-SHIP fusion proteins was determined by flow cytometry
with the anti-FcR antibody 2.4G2 (bottom panel). The data are
representative of at least two independent experiments. Multiple clones
that were analyzed showed similar results.
|
|
| |
DISCUSSION |
In the past few years since its original discovery as an IPase,
SHIP has been demonstrated to play a key role as a negative regulator
of multiple receptor systems. While SHIP's role as the mediator of the
potent negative signal delivered through FcRIIB1 is established, the
molecular mechanism(s) involved is less well defined. In this report,
by defining the boundaries of the catalytic and noncatalytic regions of
SHIP, we demonstrate that the recruitment of an enzymatically active
SHIP to the FcRIIB1 alone is not sufficient for
FcRIIB1/SHIP-mediated inhibition of the BCR signals. We show that
the noncatalytic region in the C terminus of SHIP plays an essential
role in SHIP function in vivo. While the two tyrosines Y917 and Y1020
appear to be important in SHIP function, our studies with Shc-deficient
cells suggest that the binding of Shc to these sites is not required
for SHIP-mediated inhibition of calcium flux. Studies with
membrane-targeted SHIP proteins indicate that the C terminus of SHIP,
at least in part, functions through stabilizing SHIP localization at
the membrane. Taken together, these data suggest that the C-terminal
190 amino acids of SHIP play a critical role in SHIP function in B
cells and may also be required in various other systems where SHIP
functions as a negative regulator of signaling.
Interestingly, the noncatalytic regions of the 145-kDa form of human
and murine SHIP are highly conserved (greater than 90% amino acid
identity), suggesting an evolutionarily conserved role for these
regions. Different isoforms of SHIP and cleavage products have been
detected in hematopoietic cells and have been implicated to perform
specific functions (10, 15, 41). Lucas and Rohrschneider have reported the regulated expression of a 135-kDa form of SHIP that
appears during myeloid lineage development, carrying an internal deletion between residues 920 and 980 (41). Since our data
indicate that the IPase domain of SHIP exists between residues 400 and 866, essentially all of the isoforms detected thus far must carry an
intact IPase domain but differ in the noncatalytic regions. Given our
finding that the noncatalytic regions of SHIP play a critical role in
FcR signaling, the differences in the regions outside the enzymatic
domain could determine the specific function for the different isoforms.
It is also noteworthy that the noncatalytic regions of SHIP are not
conserved in other non-SH2-containing 5'-IPases. The phenotype of
SHIP-deficient mice, in which other 5'-IPases are apparently expressed
in hematopoietic cells but are unable to substitute for SHIP function,
suggests an essential role for these noncatalytic regions. In this
regard, we found that expression of other 5'-IPases is unable to
reconstitute a SHIP-deficient B-cell line even when targeted to the FcR
(M. J. Aman et al., unpublished data). As mentioned earlier, the
IPase domain of SHIP is larger than what is predicted for other
5'-IPases. Whether the failure of these other 5'-IPases to substitute
for SHIP is due to the unique role played by SHIP's noncatalytic
regions or the unique IPase domain of SHIP or both remains to be
determined. We also observed that the murine SHIP, while quite capable
of reconstituting the SHIP deficiency, may be less efficient than the
endogenous chicken SHIP in the DT40 cells. This stems from the
diminished phosphorylation of HA-tagged murine SHIP that we observed
compared with endogenous SHIP, despite higher expression of the tagged
protein. The cause for this difference is unclear and awaits the
cloning of chicken SHIP cDNA.
While our data demonstrate a requirement for the C terminus of SHIP in
FcRIIB1/SHIP-mediated inhibition of calcium signaling, precisely how
this region contributes to SHIP function is not clear. Several, not
mutually exclusive, possibilities exist. For example, the C terminus
could help stabilize localization of SHIP at the membrane. Although the
SH2 domain of SHIP has been shown to bind to the ITIM motif in the
cytoplasmic tail of the FcRIIB1 receptor, the kinetics or stability
of this interaction at the membrane has not yet been determined. The C
terminus of SHIP may stabilize the FcR-SHIP complex either directly or
indirectly through interacting with other proteins. Alternatively,
C-terminal interactions may be required for efficient localization to
specific membrane compartments within cells, where the calcium signals
may be initiated. While a role for the C terminus in stabilizing SHIP
interaction at the membrane is suggested by the
Fc-SHIP1-900 construct, it is noteworthy that the
constitutive presence of this protein on the membrane or the topology
or turnover rate of the Fc-SHIP protein may have also contributed to
this effect.
Protein secondary-structure predictions of the region beyond residue
866 suggest a predominantly unstructured region. This is not
unexpected, given the numerous prolines throughout this region. This
implies that the regulation of SHIP function by the C terminus is most
likely mediated through proteins that interact with this region. In
this regard, we looked at the significance of the best-characterized
protein known to bind to SHIP, Shc. While the mutations of the
tyrosines previously identified as Shc binding sites appeared to play a
role in SHIP function, Shc-deficient cells showed efficient
FcRIIB1-mediated inhibition of calcium flux. This suggested that
Shc-SHIP complex formation is not required for this inhibition.
However, it is noteworthy that we observed an unexpected role for
Shc-SHIP complex formation in efficient Shc phosphorylation. The
precise role of Shc-SHIP complex formation in regulating
FcRIIB1-mediated signaling is unclear. Although a SHIP-mediated
sequestration of Shc away from Grb2, and subsequent inhibition of the
Ras/mitogen-activated protein kinase pathway was proposed initially
(56), this has not been confirmed by others
(19; our unpublished observations). Nevertheless, it appears that Shc phosphorylation is regulated through its interaction with SHIP and may have functional consequences that remain to be elucidated.
A recent report by Gupta et al. has suggested that the p85 subunit of
PI3K (via its SH2 domain) can interact with the Y917 site on SHIP
(18). The failure to interact with p85 or other SH2- or
phosphotyrosine binding domain-containing proteins might also have
contributed to the deficiency in function of the
SHIPY917F/1020F mutant. In addition, p62 Dok, originally
identified as a Ras-GAP binding protein, has also been shown to
interact via its phosphotyrosine binding domain with the two tyrosines
in the C terminus of SHIP (J. C. Cambier, personal communication).
The significance of p85 and p62 Dok interactions with SHIP in
regulating SHIP function remains to be established. Besides the two
tyrosines Y917 and Y1020, there are also four proline-rich motifs in
the C terminus of SHIP which can bind Grb2 (9, 29) or other
SH3 domain-containing proteins. Grb2 has been shown to interact via its
SH3 domain with proline-rich regions of SHIP and concurrently via its
SH2 domain with phosphorylated Shc (19). Although we have
failed to see a role for Shc-SHIP complex formation in inhibition of
calcium flux, the direct binding of Grb2 and its regulation of SHIP
function are still possible. The precise role of the proline-rich
regions and the involvement of Grb2 are currently under investigation.
Another potential role for the C terminus could be in facilitating
substrate accessibility for SHIP. The calcium inhibition profile of the
membrane-targeted Fc-SHIP1-900 protein is not the same
as that of Fc-SHIPwt. We consistently observed that the
membrane-targeted Fc-SHIP is more potent in inhibiting BCR-mediated calcium flux than wt SHIP, possibly due to a greater fraction of SHIP
molecules being present on the membrane (data not shown). This may also
be due to the topology of the Fc-SHIP proteins on the membrane or to
lower turnover of Fc-SHIP from the membrane. If the sole function of
the C terminus were to stabilize SHIP interaction at the membrane, we
would have seen comparable inhibition with Fc-SHIP1-900
and Fc-SHIPwt. Perhaps another role for the C terminus
of SHIP may be to provide better accessibility to the substrate PIP3. A
study of the phospholipid contents of the NHK96 and LS5 cell lines
showed that PIP3 makes up less than 0.01% of the total cellular
phospholipids (59). Gold and Aebersold observed only a
modest increase in the level of PIP3 over the background upon BCR
stimulation, showing that even after activation this phospholipid is
present at very low concentrations (16). While better
accessibility to PIP3 through the C terminus is an attractive
possibility, we have not seen a difference in in vitro enzymatic
activity between SHIPwt and SHIP1-900.
However, the phosphatidylserine/PIP3 micelles used in these experiments very likely do not adequately represent the complex composition of
plasma membrane. It is conceivable that in the context of the natural
plasma membrane, the C terminus may facilitate SHIP's access to
substrate by interaction with certain membrane components or mediate
SHIP's localization to specialized membrane microdomains where PIP3 is
present or calcium signaling is initiated. Further detailed studies are
required to address this issue.
SHIP has also been shown to function as a negative regulator in many
other systems, such as stimulation via colony-stimulating factor-1,
granulocyte-macrophage colony-stimulating factor, and several other
cytokines, growth hormone, and thrombin (24, 35, 51, 58).
While there is involvement of calcium in some cases, there is no
calcium flux in others. Interestingly, SHIP-deficient mice exhibit
defects in a number of different hematopoietic lineages, and studies
with these mice clearly suggest a role for SHIP in setting thresholds
during cytokine stimulation and proliferation in the myeloid lineage
(23, 39, 40). Whether the C terminus is also required for
SHIP-mediated regulation of these events remains to be determined.
Given the crucial role played by SHIP in multiple receptor systems, the
data presented in this report provide the initial steps toward a better
molecular understanding of negative regulation through SHIP.
| |
ACKNOWLEDGMENTS |
We thank Tomo Kurosaki for providing us with the DT40 cell lines
and the FcRIIB1 cDNA and Gerald Krystal for the original SHIP cDNA.
We thank Anke Klippel for purified p110* protein and Glen Prestwich and
Andrew Morris for IP4 and PIP2, respectively. We thank Ulrike Lorenz
for critical reading of the manuscript.
This work was supported by an RO1 grant from the National Institutes of
Health and by a grant from the Jeffress Gwathmy Memorial Trust (to
K.S.R.). M.J.A. was supported by an NIH Immunology Training Grant.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Carter
Immunology Center, Bldg. MR4, Rm 4012F, HSC, University of Virginia,
Charlottesville, VA 22908. Phone: (804) 243-6093. Fax: (804) 924-1221. E-mail: kr4h{at}virginia.edu.
| |
REFERENCES |
| 1.
|
Aman, M. J.,
T. D. Lamkin,
H. Okada,
T. Kurosaki, and K. S. Ravichandran.
1998.
The inositol phosphatase SHIP inhibits Akt/PKB activation in B cells.
J. Biol. Chem.
273:33922-33928[Abstract/Free Full Text].
|
| 2.
|
Ashman, R. F.,
D. Peckham, and L. L. Stunz.
1996.
Fc receptor off-signal in the B cell involves apoptosis.
J. Immunol.
157:5-11[Abstract].
|
| 3.
|
Astoul, E.,
S. Watton, and D. Cantrell.
1999.
The dynamics of protein kinase B regulation during B cell antigen receptor engagement.
J. Cell Biol.
145:1511-1520[Abstract/Free Full Text].
|
| 4.
|
Bolland, S.,
R. N. Pearse,
T. Kurosaki, and J. V. Ravetch.
1998.
SHIP modulates immune receptor responses by regulating membrane association of Btk.
Immunity
8:509-516[CrossRef][Medline].
|
| 5.
|
Bolland, S., and J. V. Ravetch.
1999.
Inhibitory pathways triggered by ITIM-containing receptors.
Adv. Immunol.
72:149-177[Medline].
|
| 6.
|
Chacko, G. W.,
S. Tridandapani,
J. E. Damen,
L. Liu,
G. Krystal, and K. M. Coggeshall.
1996.
Negative signaling in B lymphocytes induces tyrosine phosphorylation of the 145-kDa inositol polyphosphate 5-phosphatase, SHIP.
J. Immunol.
157:2234-2238[Abstract].
|
| 7.
|
Crowley, M. T.,
S. L. Harmer, and A. L. DeFranco.
1996.
Activation-induced association of a 145-kDa tyrosine-phosphorylated protein with Shc and Syk in B lymphocytes and macrophages.
J. Biol. Chem.
271:1145-1152[Abstract/Free Full Text].
|
| 8.
|
Damen, J. E.,
L. Liu,
R. L. Cutler, and G. Krystal.
1993.
Erythropoietin stimulates the tyrosine phosphorylation of Shc and its association with Grb2 and a 145-Kd tyrosine phosphorylated protein.
Blood
82:2296-2303[Abstract/Free Full Text].
|
| 9.
|
Damen, J. E.,
L. Liu,
P. Rosten,
R. K. Humphries,
A. B. Jefferson,
P. W. Majerus, and G. Krystal.
1996.
The 145-kDa protein induced to associate with Shc by multiple cytokines is an inositol tetraphosphate and phosphatidylinositol 3,4,5-triphosphate 5-phosphatase.
Proc. Natl. Acad. Sci. USA
93:1689-1693[Abstract/Free Full Text].
|
| 10.
|
Damen, J. E.,
L. Liu,
M. D. Ware,
M. Ermolaeva,
P. W. Majerus, and G. Krystal.
1998.
Multiple forms of the SH2-containing inositol phosphatase, SHIP, are generated by C-terminal truncation.
Blood
92:1199-1205[Abstract/Free Full Text].
|
| 11.
|
DeFranco, A. L.,
V. W. Chan, and C. A. Lowell.
1998.
Positive and negative roles of the tyrosine kinase Lyn in B cell function.
Semin. Immunol.
10:299-307[CrossRef][Medline].
|
| 12.
|
Diegel, M. L.,
B. M. Rankin,
J. B. Bolen,
P. M. Dubois, and P. A. Kiener.
1994.
Cross-linking of Fc gamma receptor to surface immunoglobulin on B cells provides an inhibitory signal that closes the plasma membrane calcium channel.
J. Biol. Chem.
269:11409-11416[Abstract/Free Full Text].
|
| 13.
|
Drayer, A. L.,
X. Pesesse,
F. De Smedt,
R. Woscholski,
P. Parker, and C. Erneux.
1996.
Cloning and expression of a human placenta inositol 1,3,4,5-tetrakisphosphate and phosphatidylinositol 3,4,5-trisphosphate 5-phosphatase.
Biochem. Biophys. Res. Commun.
225:243-249[CrossRef][Medline].
|
| 14.
|
Fluckiger, A. C.,
Z. Li,
R. M. Kato,
M. I. Wahl,
H. D. Ochs,
R. Longnecker,
J. P. Kinet,
O. N. Witte,
A. M. Scharenberg, and D. J. Rawlings.
1998.
Btk/Tec kinases regulate sustained increases in intracellular Ca2+ following B-cell receptor activation.
EMBO J.
17:1973-1985[CrossRef][Medline].
|
| 15.
|
Geier, S. J.,
P. A. Algate,
K. Carlberg,
D. Flowers,
C. Friedman,
B. Trask, and L. R. Rohrschneider.
1997.
The human SHIP gene is differentially expressed in cell lineages of the bone marrow and blood.
Blood
89:1876-1885[Abstract/Free Full Text].
|
| 16.
|
Gold, M. R., and R. Aebersold.
1994.
Both phosphatidylinositol 3-kinase and phosphatidylinositol 4-kinase products are increased by antigen receptor signaling in B cells.
J. Immunol.
152:42-50[Abstract].
|
| 17.
|
Gold, M. R.,
M. P. Scheid,
L. Santos,
M. Dang-Lawson,
R. A. Roth,
L. Matsuuchi,
V. Duronio, and D. L. Krebs.
1999.
The B cell antigen receptor activates the Akt (protein kinase B)/glycogen synthase kinase-3 signaling pathway via phosphatidylinositol 3-kinase.
J. Immunol.
163:1894-1905[Abstract/Free Full Text].
|
| 18.
|
Gupta, N.,
A. M. Scharenberg,
D. A. Fruman,
L. C. Cantley,
J. P. Kinet, and E. O. Long.
1999.
The SH2 domain-containing inositol 5'-phosphatase (SHIP) recruits the p85 subunit of phosphoinositide 3-kinase during FcgammaRIIb1-mediated inhibition of B cell receptor signaling.
J. Biol. Chem.
274:7489-7494[Abstract/Free Full Text].
|
| 19.
|
Harmer, S. L., and A. L. DeFranco.
1999.
The src homology domain 2-containing inositol phosphatase SHIP forms a ternary complex with Shc and Grb2 in antigen receptor-stimulated B lymphocytes.
J. Biol. Chem.
274:12183-12191[Abstract/Free Full Text].
|
| 20.
|
Hashimoto, A.,
K. Hirose,
H. Okada,
T. Kurosaki, and M. Iino.
1999.
Inhibitory modulation of B cell receptor-mediated Ca2+ mobilization by Src homology 2 domain-containing inositol 5'-phosphatase (SHIP).
J. Biol Chem
274:11203-11208[Abstract/Free Full Text].
|
| 21.
|
Hashimoto, A.,
H. Okada,
A. Jiang,
M. Kurosaki,
S. Greenberg,
E. A. Clark, and T. Kurosaki.
1998.
Involvement of guanosine triphosphatases and phospholipase C-gamma2 in extracellular signal-regulated kinase, c-Jun NH2-terminal kinase, and p38 mitogen-activated protein kinase activation by the B cell antigen receptor.
J. Exp. Med.
188:1287-1295[Abstract/Free Full Text].
|
| 22.
|
Haverstick, D. M., and L. S. Gray.
1993.
Increased intracellular Ca2+ induces Ca2+ influx in human T lymphocytes.
Mol. Biol. Cell
4:173-184[Abstract].
|
| 23.
|
Helgason, C. D.,
J. E. Damen,
P. Rosten,
R. Grewal,
P. Sorensen,
S. M. Chappel,
A. Borowski,
F. Jirik,
G. Krystal, and R. K. Humphries.
1998.
Targeted disruption of SHIP leads to hemopoietic perturbations, lung pathology, and a shortened life span.
Genes Dev.
12:1610-1620[Abstract/Free Full Text].
|
| 24.
|
Hibi, M., and T. Hirano.
1998.
Signal transduction through cytokine receptors.
Int. Rev. Immunol.
17:75-102[Medline].
|
| 25.
|
Huber, M.,
C. D. Helgason,
J. E. Damen,
L. Liu,
R. K. Humphries, and G. Krystal.
1998.
The src homology 2-containing inositol phosphatase (SHIP) is the gatekeeper of mast cell degranulation.
Proc. Natl. Acad. Sci. USA
95:11330-11335[Abstract/Free Full Text].
|
| 26.
|
Huber, M.,
C. D. Helgason,
M. P. Scheid,
V. Duronio,
R. K. Humphries, and G. Krystal.
1998.
Targeted disruption of SHIP leads to steel factor-induced degranulation of mast cells.
EMBO J.
17:7311-7319[CrossRef][Medline].
|
| 27.
|
Jacob, A.,
D. Cooney,
S. Tridandapani,
T. Kelley, and K. M. Coggeshall.
1999.
FcgammaRIIb modulation of surface immunoglobulin-induced Akt activation in murine B cells.
J. Biol. Chem.
274:13704-13710[Abstract/Free Full Text].
|
| 28.
|
Jefferson, A. B.,
V. Auethavekiat,
D. A. Pot,
L. T. Williams, and P. W. Majerus.
1997.
Signaling inositol polyphosphate-5-phosphatase. Characterization of activity and effect of GRB2 association.
J. Biol. Chem.
272:5983-5988[Abstract/Free Full Text].
|
| 29.
|
Kavanaugh, W. M.,
D. A. Pot,
S. M. Chin,
M. Deuter-Reinhard,
A. B. Jefferson,
F. A. Norris,
F. R. Masiarz,
L. S. Cousens,
P. W. Majerus, and L. T. Williams.
1996.
Multiple forms of an inositol polyphosphate 5-phosphatase form signaling complexes with Shc and Grb2.
Curr. Biol.
6:438-445[CrossRef][Medline].
|
| 30.
|
Kiener, P. A.,
M. N. Lioubin,
L. R. Rohrschneider,
J. A. Ledbetter,
S. G. Nadler, and M. L. Diegel.
1997.
Co-ligation of the antigen and Fc receptors gives rise to the selective modulation of intracellular signaling in B cells. Regulation of the association of phosphatidylinositol 3-kinase and inositol 5'-phosphatase with the antigen receptor complex.
J. Biol. Chem.
272:3838-3844[Abstract/Free Full Text].
|
| 31.
|
Klippel, A.,
W. M. Kavanaugh,
D. Pot, and L. T. Williams.
1997.
A specific product of phosphatidylinositol 3-kinase directly activates the protein kinase Akt through its pleckstrin homology domain.
Mol. Cell. Biol.
17:338-344[Abstract].
|
| 32.
|
Kurosaki, T.
1999.
Genetic analysis of B cell antigen receptor signaling.
Annu. Rev. Immunol.
17:555-592[CrossRef][Medline].
|
| 33.
|
Lamkin, T. D.,
S. F. Walk,
L. Liu,
J. E. Damen,
G. Krystal, and K. S. Ravichandran.
1997.
Shc interaction with Src homology 2 domain containing inositol phosphatase (SHIP) in vivo requires the Shc-phosphotyrosine binding domain and two specific phosphotyrosines on SHIP.
J. Biol. Chem.
272:10396-10401[Abstract/Free Full Text].
|
| 34.
|
Law, C. L.,
S. P. Sidorenko, and E. A. Clark.
1994.
Regulation of lymphocyte activation by the cell-surface molecule CD22.
Immunol. Today
15:442-449[CrossRef][Medline].
|
| 35.
|
Lin, J. X., and W. J. Leonard.
1997.
Signaling from the IL-2 receptor to the nucleus.
Cytokine Growth Factor Rev.
8:313-332[CrossRef][Medline].
|
| 36.
|
Lioubin, M. N.,
P. A. Algate,
S. Tsai,
K. Carlberg,
A. Aebersold, and L. R. Rohrschneider.
1996.
p150Ship, a signal transduction molecule with inositol polyphosphate-5-phosphatase activity.
Genes Dev.
10:1084-1095[Abstract/Free Full Text].
|
| 37.
|
Liu, L.,
J. E. Damen,
R. L. Cutler, and G. Krystal.
1994.
Multiple cytokines stimulate the binding of a common 145-kilodalton protein to Shc at the Grb2 recognition site of Shc.
Mol. Cell. Biol.
14:6926-6935[Abstract/Free Full Text].
|
| 38.
|
Liu, L.,
J. E. Damen,
M. R. Hughes,
I. Babic,
F. R. Jirik, and G. Krystal.
1997.
The Src homology 2 (SH2) domain of SH2-containing inositol phosphatase (SHIP) is essential for tyrosine phosphorylation of SHIP, its association with Shc, and its induction of apoptosis.
J. Biol. Chem.
272:8983-8988[Abstract/Free Full Text].
|
| 39.
|
Liu, Q.,
A. J. Oliveira-Dos-Santos,
S. Mariathasan,
D. Bouchard,
J. Jones,
R. Sarao,
I. Kozieradzki,
P. S. Ohashi,
J. M. Penninger, and D. J. Dumont.
1998.
The inositol polyphosphate 5-phosphatase ship is a crucial negative regulator of B cell antigen receptor signaling.
J. Exp. Med.
188:1333-1342[Abstract/Free Full Text].
|
| 40.
|
Liu, Q.,
T. Sasaki,
I. Kozieradzki,
A. Wakeham,
A. Itie,
D. J. Dumont, and J. M. Penninger.
1999.
SHIP is a negative regulator of growth factor receptor-mediated PKB/Akt activation and myeloid cell survival.
Genes Dev.
13:786-791[Abstract/Free Full Text].
|
| 41.
|
Lucas, D. M., and L. R. Rohrschneider.
1999.
A novel spliced form of SH2-containing inositol phosphatase is expressed during myeloid development.
Blood
93:1922-1933[Abstract/Free Full Text].
|
| 42.
|
Okada, H.,
S. Bolland,
A. Hashimoto,
M. Kurosaki,
Y. Kabuyama,
M. Iino,
J. V. Ravetch, and T. Kurosaki.
1998.
Role of the inositol phosphatase SHIP in B cell receptor-induced Ca2+ oscillatory response.
J. Immunol.
161:5129-5132[Abstract/Free Full Text].
|
| 43.
|
Ono, M.,
S. Bolland,
P. Tempst, and J. V. Ravetch.
1996.
Role of the inositol phosphatase SHIP in negative regulation of the immune system by the receptor Fc(gamma)RIIB.
Nature
383:263-266[CrossRef][Medline].
|
| 44.
|
Ono, M.,
H. Okada,
S. Bolland,
S. Yanagi,
T. Kurosaki, and J. V. Ravetch.
1997.
Deletion of SHIP or SHP-1 reveals two distinct pathways for inhibitory signaling.
Cell
90:293-301[CrossRef][Medline].
|
| 45.
|
Osborne, M. A.,
G. Zenner,
M. Lubinus,
X. Zhang,
Z. Songyang,
L. C. Cantley,
P. Majerus,
P. Burn, and J. P. Kochan.
1996.
The inositol 5'-phosphatase SHIP binds to immunoreceptor signaling motifs and responds to high affinity IgE receptor aggregation.
J. Biol. Chem.
271:29271-29278[Abstract/Free Full Text].
|
| 46.
|
Pantoliano, M. W.,
R. E. Bird,
S. Johnson,
E. D. Asel,
S. W. Dodd,
J. F. Wood, and K. D. Hardman.
1991.
Conformational stability, folding, and ligand-binding affinity of single-chain Fv immunoglobulin fragments expressed in Escherichia coli.
Biochemistry
30:10117-10125[CrossRef][Medline].
|
| 47.
|
Pearse, R. N.,
T. Kawabe,
S. Bolland,
R. Guinamard,
T. Kurosaki, and J. V. Ravetch.
1999.
SHIP recruitment attenuates Fc gamma RIIB-induced B cell apoptosis.
Immunity
10:753-60[CrossRef][Medline].
|
| 48.
|
Ravetch, J. V.
1997.
Fc receptors.
Curr. Opin. Immunol.
9:121-125[CrossRef][Medline].
|
| 49.
|
Ravetch, J. V., and R. A. Clynes.
1998.
Divergent roles for Fc receptors and complement in vivo.
Annu. Rev. Immunol.
16:421-432[CrossRef][Medline].
|
| 50.
|
Ravichandran, K. S.,
K. K. Lee,
Z. Songyang,
L. C. Cantley,
P. Burn, and S. J. Burakoff.
1993.
Interaction of Shc with the zeta chain of the T cell receptor upon T cell activation.
Science
262:902-905[Abstract/Free Full Text].
|
| 51.
|
Rohrschneider, L. R.,
R. P. Bourette,
M. N. Lioubin,
P. A. Algate,
G. M. Myles, and K. Carlberg.
1997.
Growth and differentiation signals regulated by the M-CSF receptor.
Mol. Reprod. Dev.
46:96-103[CrossRef][Medline].
|
| 52.
|
Saxton, T. M.,
I. van Oostveen,
D. Bowtell,
R. Aebersold, and M. R. Gold.
1994.
B cell antigen receptor cross-linking induces phosphorylation of the p21ras oncoprotein activators SHC and mSOS1 as well as assembly of complexes containing SHC, GRB-2, mSOS1, and a 145-kDa tyrosine-phosphorylated protein.
J. Immunol.
153:623-636[Abstract].
|
| 53.
|
Scharenberg, A. M.,
O. El-Hillal,
D. A. Fruman,
L. O. Beitz,
Z. Li,
S. Lin,
I. Gout,
L. C. Cantley,
D. J. Rawlings, and J. P. Kinet.
1998.
Phosphatidylinositol-3,4,5-trisphosphate (PtdIns-3,4,5-P3)/Tec kinase-dependent calcium signaling pathway: a target for SHIP-mediated inhibitory signals.
EMBO J.
17:1961-1972[CrossRef][Medline].
|
| 54.
|
Smit, L.,
A. M. de Vries-Smits,
J. L. Bos, and J. Borst.
1994.
B cell antigen receptor stimulation induces formation of a Shc-Grb2 complex containing multiple tyrosine-phosphorylated proteins.
J. Biol. Chem.
269:20209-20212[Abstract/Free Full Text].
|
| 55.
|
Takata, M.,
H. Sabe,
A. Hata,
T. Inazu,
Y. Homma,
T. Nukada,
H. Yamamura, and T. Kurosaki.
1994.
Tyrosine kinases Lyn and Syk regulate B cell receptor-coupled Ca2+ mobilization through distinct pathways.
EMBO J.
13:1341-1349[Medline].
|
| 56.
|
Tridandapani, S.,
G. W. Chacko,
J. R. Van Brocklyn, and K. M. Coggeshall.
1997.
Negative signaling in B cells causes reduced Ras activity by reducing Shc-Grb2 interactions.
J. Immunol.
158:1125-1132[Abstract].
|
| 57.
|
Ware, M. D.,
P. Rosten,
J. E. Damen,
L. Liu,
R. K. Humphries, and G. Krystal.
1996.
Cloning and characterization of human SHIP, the 145-kD inositol 5-phosphatase that associates with SHC after cytokine stimulation.
Blood
88:2833-2840[Abstract/Free Full Text].
|
| 58.
|
Yamauchi, T.,
K. Ueki,
K. Tobe,
H. Tamemoto,
N. Sekine,
M. Wada,
M. Honjo,
M. Takahashi,
T. Takahashi,
H. Hirai,
T. Tsushima,
Y. Akanuma,
T. Fujita,
I. Komuro,
Y. Yazaki, and T. Kadowaki.
1998.
Growth hormone-induced tyrosine phosphorylation of EGF receptor as an essential element leading to MAP kinase activation and gene expression.
Endocr. J.
45(Suppl.):S27-S31.
|
| 59.
|
Zhang, X.,
P. A. Hartz,
E. Philip,
L. C. Racusen, and P. W. Majerus.
1998.
Cell lines from kidney proximal tubules of a patient with Lowe syndrome lack OCRL inositol polyphosphate 5-phosphatase and accumulate phosphatidylinositol 4,5-bisphosphate.
J. Biol. Chem.
273:1574-1582[Abstract/Free Full Text].
|
Molecular and Cellular Biology, May 2000, p. 3576-3589, Vol. 20, No. 10
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Ai, J., Maturu, A., Johnson, W., Wang, Y., Marsh, C. B., Tridandapani, S.
(2006). The inositol phosphatase SHIP-2 down-regulates Fc{gamma}R-mediated phagocytosis in murine macrophages independently of SHIP-1. Blood
107: 813-820
[Abstract]
[Full Text]
-
Lesourne, R., Fridman, W. H., Daeron, M.
(2005). Dynamic Interactions of Fc{gamma} Receptor IIB with Filamin-Bound SHIP1 Amplify Filamentous Actin-Dependent Negative Regulation of Fc{epsilon} Receptor I Signaling. J. Immunol.
174: 1365-1373
[Abstract]
[Full Text]
-
Tomlinson, M. G., Heath, V. L., Turck, C. W., Watson, S. P., Weiss, A.
(2004). SHIP Family Inositol Phosphatases Interact with and Negatively Regulate the Tec Tyrosine Kinase. J. Biol. Chem.
279: 55089-55096
[Abstract]
[Full Text]
-
Isnardi, I., Lesourne, R., Bruhns, P., Fridman, W. H., Cambier, J. C., Daeron, M.
(2004). Two Distinct Tyrosine-based Motifs Enable the Inhibitory Receptor Fc{gamma}RIIB to Cooperatively Recruit the Inositol Phosphatases SHIP1/2 and the Adapters Grb2/Grap. J. Biol. Chem.
279: 51931-51938
[Abstract]
[Full Text]
-
Wang, Y., Keogh, R. J., Hunter, M. G., Mitchell, C. A., Frey, R. S., Javaid, K., Malik, A. B., Schurmans, S., Tridandapani, S., Marsh, C. B.
(2004). SHIP2 Is Recruited to the Cell Membrane upon Macrophage Colony-Stimulating Factor (M-CSF) Stimulation and Regulates M-CSF-Induced Signaling. J. Immunol.
173: 6820-6830
[Abstract]
[Full Text]
-
Fang, H., Pengal, R. A., Cao, X., Ganesan, L. P., Wewers, M. D., Marsh, C. B., Tridandapani, S.
(2004). Lipopolysaccharide-Induced Macrophage Inflammatory Response Is Regulated by SHIP. J. Immunol.
173: 360-366
[Abstract]
[Full Text]
-
Aydar, Y., Balogh, P., Tew, J. G., Szakal, A. K.
(2003). Altered Regulation of Fc{gamma}RII on Aged Follicular Dendritic Cells Correlates with Immunoreceptor Tyrosine-Based Inhibition Motif Signaling in B Cells and Reduced Germinal Center Formation. J. Immunol.
171: 5975-5987
[Abstract]
[Full Text]
-
Galandrini, R., Tassi, I., Mattia, G., Lenti, L., Piccoli, M., Frati, L., Santoni, A.
(2002). SH2-containing inositol phosphatase (SHIP-1) transiently translocates to raft domains and modulates CD16-mediated cytotoxicity in human NK cells. Blood
100: 4581-4589
[Abstract]
[Full Text]
-
Marion, E., Kaisaki, P. J., Pouillon, V., Gueydan, C., Levy, J. C., Bodson, A., Krzentowski, G., Daubresse, J.-C., Mockel, J., Behrends, J., Servais, G., Szpirer, C., Kruys, V., Gauguier, D., Schurmans, S.
(2002). The Gene INPPL1, Encoding the Lipid Phosphatase SHIP2, Is a Candidate for Type 2 Diabetes In Rat and Man. Diabetes
51: 2012-2017
[Abstract]
[Full Text]
-
Tridandapani, S., Siefker, K., Teillaud, J.-L., Carter, J. E., Wewers, M. D., Anderson, C. L.
(2002). Regulated Expression and Inhibitory Function of Fcgamma RIIb in Human Monocytic Cells. J. Biol. Chem.
277: 5082-5089
[Abstract]
[Full Text]
-
Kato, I., Takai, T., Kudo, A.
(2002). The Pre-B Cell Receptor Signaling for Apoptosis Is Negatively Regulated by Fc{gamma}RIIB. J. Immunol.
168: 629-634
[Abstract]
[Full Text]
-
Dyson, J. M., O'Malley, C. J., Becanovic, J., Munday, A. D., Berndt, M. C., Coghill, I. D., Nandurkar, H. H., Ooms, L. M., Mitchell, C. A.
(2001). The SH2-containing inositol polyphosphate 5-phosphatase, SHIP-2, binds filamin and regulates submembraneous actin. JCB
155: 1065-1080
[Abstract]
[Full Text]
-
Aman, M. J., Tosello-Trampont, A.-C., Ravichandran, K.
(2001). Fcgamma RIIB1/SHIP-mediated Inhibitory Signaling in B Cells Involves Lipid Rafts. J. Biol. Chem.
276: 46371-46378
[Abstract]
[Full Text]
-
Brauweiler, A., Tamir, I., Marschner, S., Helgason, C. D., Cambier, J. C.
(2001). Partially Distinct Molecular Mechanisms Mediate Inhibitory Fc{{gamma}}RIIB Signaling in Resting and Activated B Cells. J. Immunol.
167: 204-211
[Abstract]
[Full Text]
-
Damen, J. E., Ware, M. D., Kalesnikoff, J., Hughes, M. R., Krystal, G.
(2001). SHIP's C-terminus is essential for its hydrolysis of PIP3 and inhibition of mast cell degranulation. Blood
97: 1343-1351
[Abstract]
[Full Text]
-
Fong, D. C., Brauweiler, A., Minskoff, S. A., Bruhns, P., Tamir, I., Mellman, I., Daeron, M., Cambier, J. C.
(2000). Mutational Analysis Reveals Multiple Distinct Sites Within Fc{gamma} Receptor IIB That Function in Inhibitory Signaling. J. Immunol.
165: 4453-4462
[Abstract]
[Full Text]
-
Taylor, V., Wong, M., Brandts, C., Reilly, L., Dean, N. M., Cowsert, L. M., Moodie, S., Stokoe, D.
(2000). 5' Phospholipid Phosphatase SHIP-2 Causes Protein Kinase B Inactivation and Cell Cycle Arrest in Glioblastoma Cells. Mol. Cell. Biol.
20: 6860-6871
[Abstract]
[Full Text]
-
March, M. E., Lucas, D. M., Aman, M. J., Ravichandran, K. S.
(2000). p135 Src Homology 2 Domain-containing Inositol 5'-Phosphatase (SHIPbeta ) Isoform Can Substitute for p145 SHIP in Fcgamma RIIB1-mediated Inhibitory Signaling in B Cells. J. Biol. Chem.
275: 29960-29967
[Abstract]
[Full Text]
-
Marion, E., Kaisaki, P. J., Pouillon, V., Gueydan, C., Levy, J. C., Bodson, A., Krzentowski, G., Daubresse, J.-C., Mockel, J., Behrends, J., Servais, G., Szpirer, C., Kruys, V., Gauguier, D., Schurmans, S.
(2002). The Gene INPPL1, Encoding the Lipid Phosphatase SHIP2, Is a Candidate for Type 2 Diabetes In Rat and Man. Diabetes
51: 2012-2017
[Abstract]
[Full Text]
Top
Abstract
Introduction
