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J. Biol. Chem., Vol. 275, Issue 27, 20480-20487, July 7, 2000
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From the
Received for publication, November 24, 1999, and in revised form, April 25, 2000
Fc Clustering of the Fc The biochemical pathways initiated by Fc Studies from our laboratory (8) and others (9, 10) have demonstrated
that the tyrosine kinase Syk is directly recruited to the
phosphorylated ITAM of the receptor. Syk recruitment is followed by the
recruitment of other SH2 domain-containing enzymes such as PLC Although membrane recruitment is essential for stimulation of these
enzymes in phagocytosis, it is unclear how membrane recruitment is
elicited by Fc Earlier studies from our laboratory (24) revealed an undefined 36-kDa
phosphoprotein associated with the Fc LAT, a membrane-associated adapter molecule that exists as 36- and
38-kDa isoforms, was originally cloned from T cells (25). This protein
lacks any intrinsic enzymatic activity but facilitates enzyme function
by serving as an adapter that recruits SH2 domain-containing enzymes
and enzyme-adapter complexes (25). Palmitoylation of LAT targets it to
glycolipid-enriched domains in the membrane (26). Mutational analyses
indicated that localization of LAT to the lipid rafts is crucial for
its function (27). T cell receptor cross-linking leads to
phosphorylation of LAT and its association with a number of signaling
proteins. The importance of LAT in T cell signaling by the T cell
antigen receptor (TCR) is demonstrated by the inability of
LAT-deficient cell lines to respond to TCR cross-linking (28, 29).
Overexpression of a dominant-negative mutant of LAT, that is incapable
of associating with some key SH2 domain proteins, severely impairs
TCR-induced calcium flux, ERK activation, and production of
interleukin-2 in Jurkat cells (25). The expression of LAT also appears
to be critical for T cell development, as LAT knockout mice display a
lack of mature T cells in the periphery (30).
Here, we report that LAT is expressed in myeloid cells,
co-immunoprecipitates with Fc Cells, Antibodies, and Reagents--
THP-1, U937, Raji, Jurkat,
and COS-7 cells were obtained from ATCC. COS-7 cells were maintained in
Dulbecco's modified Eagle's medium supplemented with 10% fetal
bovine serum. All other cells were maintained in RPMI, supplemented
with 10% fetal bovine serum. Anti-Fc Isolation of Peripheral Blood Monocytes (PBM)--
Peripheral
blood mononuclear cells were first isolated by density gradient
centrifugation over Histopaque (Sigma). Monocytes were then purified
from the peripheral blood mononuclear cells by negative selection using
the MACs Monocyte Isolation Kit (Miltenyi Biotech). Briefly, peripheral
blood mononuclear cells were first treated with FcR blocking Reagent
(hIgG), followed by a Hapten-Antibody Mixture (mixture of monoclonal
hapten-conjugated CD3, CD7, CD19, CD45RA, CD56, and anti-IgE
antibodies). The labeled cells were further treated with MACS
anti-hapten magnetic microbeads that were conjugated to a monoclonal
anti-hapten antibody. The cells were then passed over a MACS column,
and the effluent was collected as the negative fraction representing
enriched monocytes. The monocytes thus purified were subsequently
analyzed for purity by double labeling with CD14-PE and CD45-FITC
antibodies followed by flow cytometry. Data from 10,000 cells indicated
that the isolated monocytes were 100% CD14 positive.
Culture of Murine Bone Marrow-derived
Macrophages--
Strain-matched wild type and LAT-deficient mice were
a kind gift from Dr. Paul E. Love (National Institutes of Health,
Bethesda, MD). Bone marrow macrophages (BMM) were derived as described
previously (31). Briefly, bone marrow cells were cultured in RPMI
containing 5% fetal bovine serum and supplemented with 50 ng/ml CSF-1
for 5 days. The BMMs were dissociated from the plates with Cell
Dissociation Buffer (Life Technologies, Inc.) and analyzed for Fc
receptor expression by flow cytometry, expression of LAT by Western
blotting, and for their ability to bind and ingest IgG-coated sheep RBCs.
Immunoprecipitation and Western Blotting--
THP-1 cells and
transfected COS-7 cells were activated by clustering Fc Transfection--
COS-7 cells were transfected as described
previously (32). Briefly, cells were grown on culture dishes until they
were 60-70% confluent. 2 µg of cDNA for Fc Preparation of IgG-coated Sheep RBCs--
Sheep RBCs (Colorado
Serum, Denver, CO) were washed in phosphate-buffered saline, and
labeled overnight with 0.1 mg/ml FITC in phosphate-buffered saline at
4 °C. FITC-labeled cells were then washed in phosphate-buffered
saline and incubated with a subagglutinating dose of rabbit anti-sheep
RBC IgG (Diamedix, Miami, FL) at 37 °C for 1 h. Unbound IgG was
removed by washing the cells with phosphate-buffered saline.
Phagocytosis Assay--
IgG-coated SRBCs described above were
added to COS-7 transfectants in suspension, and the cells were pelleted
by low speed centrifugation to increase contact between SRBCs and
phagocytes. The samples were prepared in duplicate and incubated for
1 h at either 4 °C to study binding, or 37 °C to study
phagocytosis. All cells were fixed in 1% paraformaldehyde and mounted
on slides to be viewed under a fluorescence microscope. For the
phagocytosis assay, cells were subjected to brief hypotonic lysis with
water to remove externally bound RBCs prior to fixation in
paraformaldehyde. The ability of the transfected COS-7 cells to bind
IgG-coated targets was expressed as the percentage of cells that each
bound three or more SRBCs ("Rosetting Activity," Table I). That the binding was via the transfected Fc receptors was confirmed by the lack
of binding observed in untransfected COS-7 cells. As an additional
control, all cells were also incubated with fluoresceinated RBCs that
were not opsonized with IgG. No binding or phagocytosis was seen in any
of the samples treated with non-opsonized RBCs. Phagocytosis was
measured by counting the total number of RBCs ingested by 200 transfected COS-7 cells ("Phagocytic Index," Table I). The
experiment was repeated three times.
Murine bone-marrow macrophages from wild type and LAT deficient mice
were dissociated from culture dishes and treated with IgG-coated SRBCs
by methods described above. The total number of SRBCs bound by 500 macrophages was counted and expressed as the "Binding Index" (Fig.
6A). The number of SRBCs ingested by 500 macrophages is
expressed as the "Phagocytic Index" (Fig. 6A). The
experiment was repeated twice with macrophages derived from two sets of mice.
Measurement of Receptor Expression by Flow Cytometry--
Murine
BMMs were tested for expression of Fc
Transfected COS-7 cells were analyzed for Fc Fc LAT Is Expressed in Monocytes and Is Phosphorylated in Response to
Fc
To further characterize the kinetics of phosphorylation of the two
isoforms of LAT upon Fc LAT Co-immunoprecipitates with Fc LAT Associates Inducibly with SH2-domain Containing Signaling
Proteins--
Having established that LAT is expressed in myeloid
cells and is phosphorylated in response to Fc LAT Influences Phagocytic Efficiency of Fc
Earlier studies in T cells established that mutation of LAT at
Tyr171 and Tyr191 completely abrogates
association with p85 and Grb2, and partially reduces binding to PLC
To measure phagocytic efficiency, similar transfected samples were
incubated at 37 °C and subsequently subjected to hypotonic lysis
with dH2O to remove unbound and externally bound SRBCs. The
cells were subsequently fixed in 1% paraformaldehyde, mounted on
slides, and analyzed by fluorescence microscopy. The number of SRBCs
ingested by 100 phagocytic cells was counted and expressed as the
phagocytic index (Table I); data from three separate experiments are
shown. COS-7 cells overexpressing wild type LAT displayed ~25%
greater phagocytic efficiency than those that overexpressed the Tyr to
Phe LAT mutant or no transfected LAT (p value < 0.001). Western blotting with anti-LAT antibody indicated almost equal levels of expression of the transfected wild type LAT and LAT Tyr to
Phe mutant (Fig. 5B). Interestingly, the antibody also detected low levels of p36 and p38 LAT in COS-7 cells, migrating slightly faster than the Myc-tagged LAT. The possible presence of
endogenously expressed LAT in COS-7 cells could explain the small
influence of the transfected LAT proteins on phagocytosis. Expression
of the BMMs from LAT-deficient Mice Display Reduced Phagocytic
Efficiency--
The functional studies using the COS-7 model suggest
that LAT supports phagocytosis by Fc Here, we report that LAT is an additional and important component
of Fc While Syk (8) and PI 3-kinase (22) appear to be directly recruited to
Fc The importance of lipid rafts in signal transduction is becoming
increasingly evident. Lipid rafts are biochemically distinct regions of
the plasma membrane that are enriched in sphingolipids and cholesterol
(40, 41). Recent studies in T cells indicate that several key signaling
molecules are localized in lipid rafts, and that TCR clustering is
followed by a rearrangement of the rafts in the plasma membrane (42).
Studies in T cells indicate that LAT is palmitoylated, that it likewise
resides in glycolipid-enriched lipid rafts (26), and that targeting of
LAT to the lipid rafts is critical for its function (28). The TCR
either moves into the rafts upon its clustering (43, 44), or is
constitutively associated with lipid rafts (45). Similarly, the Fc In conclusion, we have characterized the initial events that occur upon
Fc We are grateful to Dr. Lawrence E. Samelson,
Dr. Jeffrey Ravetch, Dr. Jean-Pierre Kinet, and Dr. Paul E. Love for
kindly providing the plasmids and animals used in this study. We also
thank Dr. Mark Wewers and Dr. Andrea Doseff for the many helpful discussions.
*
This work was supported in part by National Institues of
Health Grants CA44983 and HD35121.The costs of publication of this article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
Fellow of the Leukemia and Lymphoma Society (formerly Leukemia
Society of America).
**
Scholar of the Leukemia Society of America.
Published, JBC Papers in Press, April 25, 2000, DOI 10.1074/jbc.M909462199
The abbreviations used are:
Fc
The Adapter Protein LAT Enhances Fc
Receptor-mediated Signal
Transduction in Myeloid Cells*
§,,,
**, and
Department of Internal Medicine, The Ohio
State University, Columbus, Ohio 43210, the ¶ Laboratory of
Pathology, NCI, National Institutes of Health, Bethesda, Maryland
20877, and the Department of Immunobiology and Cancer,
Oklahoma Medical Research Foundation,
Oklahoma City, Oklahoma 73104
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
R clustering in monocytes initiates a
cascade of signaling events that culminate in biological responses such
as phagocytosis, production of inflammatory cytokines, and generation
of reactive oxygen species. We have identified and determined the
function of the adapter protein linker of activation of T cell (LAT) in FcR-mediated signaling and function. Clustering of FcRs on the human monocytic cell line, THP-1, induces phosphorylation of a major
36-kDa protein which immunoreacts with anti-LAT antisera. Our data
indicate that although both the 36-kDa and 38-kDa isoforms of LAT are
expressed in THP-1 and U937 human monocytic cells, FcR clustering
induces phosphorylation of the 36-kDa isoform only.
Co-immunoprecipitation experiments revealed a constitutive association
of p36 LAT with both FcRI and FcRIIa immunoprecipitates, and an
activation-induced association of LAT with PLC1, Grb2, and the p85
subunit of phosphatidylinositol 3-kinase. Transient transfection
experiments in COS-7 cells indicated that overexpression of a wild type
but not a dominant-negative LAT, that is incapable of binding to p85,
enhances phagocytosis by FcRI. Furthermore, bone marrow-derived
macrophages from LAT-deficient mice displayed reduced phagocytic
efficiency in comparison to the macrophages from wild-type mice. Thus,
we conclude that p36 LAT serves to enhance FcR-induced signal
transduction in myeloid cells.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
receptors
(FcR)1 on
monocytes/macrophages initiates a series of intracellular biochemical
events that are necessary for induction of the various biological
outcomes, such as phagocytosis, production of inflammatory cytokines,
and generation of reactive oxygen species. Receptor clustering is the
result of FcR engagement of IgG-coated soluble or particulate antigens and is distinct from FcR occupancy, which does not promote signaling biochemistry or biology (reviewed in Ref. 1). Phagocytosis of
IgG-coated particulate antigens is elicited by all IgG receptors, with
the notable exception of FcRIIb (reviewed in Ref. 2), and is an
essential function of the innate immune system.
Rs leading to phagocytosis
is highly analogous to that of other immunoreceptors. Thus, FcR
aggregation by IgG-coated particulate antigen induces the activity of
Src kinases, which phosphorylate a conserved receptor-associated amino
acid motif known as the immunoreceptor tyrosine-based activation motif
(ITAM) (2-4). ITAMs of the FcRs are found in the
receptor-associated -subunit except in the case of FcRIIa (4, 5),
which uniquely expresses the ITAM within its cytoplasmic tail (5, 6).
ITAM phosphorylation initiates ITAM recruitment of a variety of enzymes that propagate the antigenic signal, and lead to and are essential for
phagocytosis (reviewed in Refs. 4 and 7). However, while reports over
the past several years have elucidated some of the FcR-triggered
signaling pathways leading to phagocytosis, the proximal events induced
by FcR clustering are not fully understood.
1, the
Grb2-Sos complex and the p85-p110 complex of PI 3-kinase (11, 12).
Translocation of PLC1 to the membrane brings it in contact with its
lipid substrate phosphatidylinositol 4,5-bisphosphate, thus generating
second messengers involved in the activation of protein kinase C and
release of intracellular stored calcium (13, 14). Association of the
Grb2-Sos complex with the membrane facilitates the activation of the
Ras/ERK pathway leading to the activation of transcription factors and
gene expression (15-17). Membrane localization of the p85 subunit of
PI 3-kinase is essential for the generation of lipid second messengers
that are involved in the activation of a number of enzymes including those that potentiate actin polymerization and cytoskeletal
rearrangements (11, 18-20). Indeed our recent experiments in
fibroblasts expressing a chimeric receptor composed of the
extracellular domain of FcRI and p85 reveals that membrane
recruitment of PI 3-kinase is necessary and sufficient to induce actin
polymerization and phagocytosis (21). Thus, recruitment of these
enzymes to the membrane is critical for their functioning.
Rs. Experiments using synthetic phosphopeptides corresponding to the phosphorylated ITAM of FcRI and FcRIIa indicated that some but not all of the above enzymes directly bind via
their SH2 domains with the ITAM (8, 11, 22). Other signaling enzymes do
not directly bind the phosphorylated ITAM, but might be recruited
through a receptor-associated adapter protein. While immunoreceptors
expressed on lymphocytes and mast cells utilize multiple ITAM-bearing
subunits to efficiently transduce signals, the -subunit is the only
ITAM-bearing molecule identified to date that associates with Fc
receptors in monocytes (23). Other FcR-associated molecules may be
present and function as an adapter protein, but are unidentified.
RI 
-chain. Experiments
presented here seeking to identify proteins phosphorylated very early
upon receptor clustering also revealed a 36-kDa phosphoprotein. Hence
we set out to determine the identity and function of pp36. Here we show
that this protein is the recently cloned adapter molecule LAT (linker
for activation of T cells).
Rs, and is phosphorylated in response to FcR clustering. Additional studies indicate that LAT associates with p85, Grb2, and PLC1 upon monocyte activation and LAT
phosphorylation. COS-7 transfectants overexpressing a wild-type LAT
displayed enhanced phagocytic efficiency, while in contrast, COS-7
transfectants overexpressing LAT Y171F/Y191F showed decreased
phagocytic efficiency. Consistent with these findings indicating a
supporting role for LAT in phagocytosis, bone marrow-derived
macrophages from wild type mice were approximately twice as efficient
at ingesting IgG-coated SRBCs as those derived from LAT-deficient
animals. Thus, we conclude that LAT is a functional component of FcR
signaling in myeloid cells, serving to recruit SH2 domain-containing
signaling proteins to the membrane.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
RI antibodies 197 and 32.2, and
anti-FcRIIa antibody IV.3 were obtained from Medarex. Rabbit
polyclonal anti-LAT antibody and anti-phosphotyrosine antibody 4G10
were purchased from UBI. Anti-p85 antibody was a generous gift from Dr.
K. Mark Coggeshall (Oklahoma Medical Research Foundation, Oklahoma
City, OK).
RI and or
FcRIIa with mAb 197 and IV.3 and goat anti-mouse Ig secondary
antibody. Resting and activated cells were lysed in TN1 buffer (50 mM Tris, pH 8.0, 10 mM EDTA, 10 mM
Na4P2O7, 10 mM NaF, 1%
Triton X-100, 125 mM NaCl, 10 mM
Na3VO4, 10 µg/ml each aprotinin and
leupeptin)), and postnuclear lysates were incubated overnight with the
antibody of interest and protein G-agarose beads (Life Technologies,
Inc.) or goat anti-mouse Ig covalently linked to Sepharose, depending
on the antibody. Immune complexes bound to beads were washed in TN1 and
boiled in SDS sample buffer (60 mM Tris, pH 6.8. 2.3% SDS,
10% glycerol, 0.01% bromphenol blue, and 5% 2-mercaptoethanol) for 5 min. Proteins were separated by SDS-PAGE, transferred to nitrocellulose
filters, probed with the antibody of interest and developed by enhanced chemiluminescence.
RI chain in
pCEXV3, kindly provided by Dr. J. Ravetch (Rockefeller University, New
York), 2 µg of -subunit cDNA in pSVL, a gift from Dr. J.-P.
Kinet (Harvard University, Boston, MA), and 4 µg of Myc-tagged, wild
type LAT or LAT Y171F/Y191F in pEF/Bos, a generous gift from D. L. E. Samelson (National Institutes of Health, Bethesda, MD) were
mixed in various combinations with LipofectAMINE 2000 reagent (Life
Technologies, Inc.). The DNA mixture was added to cells in serum-free
Dulbecco's modified Eagle's medium and incubated for 3 h at
37 °C in a CO2 incubator. The media was then replaced by
Dulbecco's modified Eagle's medium supplemented with 10% fetal
bovine serum. The cells were harvested 48 h later and analyzed for
expression of the transfected cDNAs by flow cytometry and Western
blotting. Having ensured that the various transfectants expressed
comparable levels of protein, we then examined their ability to bind
and ingest Ig-coated sheep RBCs.
Rs by incubating with
anti-FcRII/III mAb 2.4G2 (Pharmingen), at a concentration of 10 µg/ml for 30 min at 4 °C. The cells were washed and incubated with
FITC-labeled goat anti-rat Ig secondary antibody for 30 min at 4 °C.
Cells were subsequently washed, fixed in 1% paraformaldehyde, and
analyzed by flow cytometry on an Elite EPICS fluorescence-activated cell sorter (Coulter, Hialeah, FL). Data from 10,000 cells per condition were recorded to yield the percentage of cells expressing receptors (Fig. 6B).
RI expression by
incubating them with anti-FcRI mAb 197, followed by FITC-labeled goat
anti-mouse Ig secondary and subsequent flow cytometry as described
above (Table I).
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
R Clustering in THP-1 Cells Induces Phosphorylation of a Major
36-kDa Protein That Immunoreacts with Anti-LAT Antibody--
To
identify the initial events that ensue upon FcR clustering in
monocytes, we assessed tyrosine kinase activity in resting and
FcR-stimulated THP-1 cells. THP-1 cells were incubated with either
anti-FcRI mAb 197 or with anti-FcRIIa mAb IV.3 and the mAb-bound
receptors were subsequently clustered with goat anti-mouse Ig secondary
antibody. Proteins were immunoprecipitated and analyzed by Western
blotting with anti-phosphotyrosine antibody (Fig.
1, A and B, upper
panels). The results indicated a number of proteins phosphorylated
upon FcR clustering, notable among them was a 36-kDa protein that
appeared as early as 1 min after receptor clustering. To identify the
36-kDa protein, the blots were stripped and reprobed sequentially with
several antibodies against known 36-kDa proteins such as Lnk, the Fc
receptor-associated 
-chain and LAT. Of the antibodies used only
anti-LAT immunoreacted with the 36-kDa phosphoprotein in the lysates of
THP-1 cells activated by FcR clustering (Fig. 1, A and
B, lower panels).
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Fig. 1.
Fc R-clustering
induces phosphorylation of a 36-kDa protein. THP-1 cells were
activated for the times indicated in the figure by clustering either
FcRI with mAb 197 (A) or FcRIIa with mAb IV.3
(B), followed by goat anti-mouse IgG secondary antibody.
Tyrosine-phosphorylated proteins were immunoprecipitated with
anti-phosphotyrosine antibody, separated by SDS-PAGE, and analyzed by
Western blotting with anti-phosphotyrosine antibody (upper
panels). The same blots were stripped and reprobed with anti-LAT
antibody (lower panels). A whole cell lysate
(WCL) from 106 THP-1 cells was loaded in the
last lane as a positive control for Western blotting with anti-LAT
antibody. Margin numbers indicate molecular weight in
kDa.
R Clustering--
Previous studies of tissue distribution of LAT
indicated that myeloid cells did not express LAT mRNA (25). In
order to ensure that the immunoreactivity of anti-LAT antibody observed
in Fig. 1 was not an observation limited to the THP-1 cell line,
lysates of several different cell lines and primary macrophages were
analyzed by Western blotting with anti-LAT antibody. As indicated in
Fig. 2A, the two isoforms of
LAT, p36 and p38, were detected in THP-1 and U937 human monocytoid cell
lines, and 30 µg of Jurkat T cell lysate positive control (UBI),
whereas Raji B cells were negative. In parallel experiments,
lysates from murine BMM (Fig. 2B) and PBM (Fig.
2C) were probed with anti-LAT antibody. The results indicate
the presence of LAT in both murine BMMs, and in human PBMs. However, to
our surprise we found that the amount of LAT present in monocytes is
lower than that in a comparable number of Jurkat T cells. In order to
obtain an estimate of the amount of LAT expressed in monocytes
versus T cells, we used lysates from decreasing numbers of
Jurkat T cells (Fig. 2D). Results indicated that LAT
expression in monocytes is approximately 5-10% of that in Jurkat T
cells. Thus, the LAT adapter protein is expressed in T cells and
monocytes but not in B cells.
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Fig. 2.
LAT is expressed in human monocytes and is
tyrosine phosphorylated in response to Fc R
clustering and target binding. A, whole cell lysates
from 2 × 106 THP-1, U937, Raji were probed with
anti-LAT antibody. 30 µg of Jurkat lysate (UBI) was loaded in the
last lane as a positive control. B, whole cell lysates from
106 murine BMMs, Raji, and Jurkat T cells were probed with
anti-LAT antibody. C, whole cell lysates form
106 PBMs, Jurkat, U937, and Raji cells were probed with
anti-LAT antibody. D, whole cell lysates from
106 THP-1, U937, Jurkat and Raji cells were loaded in
lanes 1, 2, 3, and 8, respectively. Lanes
4-7 were loaded with whole cell lysates from 5 × 105, 2.5 × 105, 105, and
5 × 104 Jurkat T cells, respectively. The blot was
then probed with anti-LAT antibody. E-G, THP-1 cells were
activated for the indicated times by clustering either FcRI
(E) or FcRIIa (F) with receptor-specific mAbs,
or by incubating with IgG-coated SRBCs (G). Cell lysates
were immunoprecipitated with anti-LAT antibody followed by Western
blotting with anti-phosphotyrosine antibody (upper panels).
The same blots were reprobed with anti-LAT antibody (lower
panels) to ensure equal loading of protein in all lanes. Normal
rabbit IgG was used in the last lane as a control for
immunoprecipitation. Arrows indicate the position of LAT.
The p40 in F is likely FcRIIA. Also indicated in the
figure are the heavy and light chains (IgH, IgL) of the activating and
immunoprecipitating IgG antibodies.
R stimulation in monocytes, we immunoprecipitated LAT from monocytes stimulated with anti-FcR mAb
as above, or with IgG-opsonized SRBCs, the natural ligand for monocyte
FcRs. Tyrosine phosphorylation of LAT was seen as early as 30 s
in both cases, peaked at 1 min and lasted until 5 min (Fig. 2,
E-G, upper panels). Furthermore, while the 36-kDa isoform
of LAT displayed robust phosphorylation, there was no detectable
phosphorylation of the 38-kDa isoform. The blots were subsequently
probed with anti-LAT antibody to ensure equal loading of protein in all
lanes (Fig. 2, E-G, lower panels).
Rs in THP-1 Cells--
Our
earlier studies on the FcRI receptor complex had revealed a 36-kDa
phosphoprotein associated with the FcRI chain (24). To address
whether this 36-kDa protein was LAT, lysates from resting and activated
THP-1 cells were immunoprecipitated with either anti-FcRI mAb 32.2 or anti-FcRIIa mAb IV.3. The immune complexes were separated by
SDS-PAGE and analyzed by Western blotting with anti-LAT antibody (Figs.
3, A and B, upper
panels). The 36-kDa isoform of LAT was detected in both FcRI
and FcRIIa immunoprecipitates. Interestingly, the presence of LAT in
FcR immunoprecipitates was detectable in resting cells and did not
increase upon receptor clustering. No anti-LAT reactivity was seen in
additional control samples of lanes loaded with the monoclonal
antibodies without cell lysate; thus, the LAT immunoreactivity is not
an artifact of the antibodies. These data suggest that LAT may be a
component of resting, unphosphorylated FcRI and FcRIIa complexes,
as is the ITAM-containing -subunit of FcRI (23). However, it is conceivable that under the lysis conditions used in these experiments the lipid rafts are insufficiently solubilized, and that the
co-immunoprecipitation simply indicates that the two molecules reside
in the same rafts but are not physically associated. Studies to
determine the exact nature of the interaction of LAT with the FcRs
are underway.
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Fig. 3.
LAT co-immunoprecipitates with
Fc RI chain and with
FcRIIa in both resting and activated THP-1
cells. THP-1 cells were activated for 3 min by either clustering
FcRI (A) or FcRIIa (B) with mAb 197 and mAb
IV.3, followed by goat anti-mouse Ig secondary antibody, respectively.
The receptors were immunoprecipitated with mAb 32.2 and IV.3,
respectively, and the immune complexes were separated by SDS-PAGE and
analyzed by Western blotting with anti-LAT antibody. The lanes marked
C were loaded with mAb alone in the absence of cell lysate.
A whole cell lysate and a LAT immunoprecipitate were loaded as positive
controls in the last lanes of A and B,
respectively. The blot from B was reprobed with
anti-FcRIIa Ab 260 (lower panel). Arrows
indicate the position of LAT. These results are representative of four
separate experiments.
R activation, we next
examined its part in FcR-mediated function in myeloid cells. LAT
contains several tyrosines that are potential phosphorylation sites and fit a YXXX consensus motif for SH2-domain binding (33).
Studies in T cells and NK cells indicated that phosphorylated LAT
associated with several SH2 domain-containing proteins, thereby
supporting their membrane translocation (25, 28, 29, 34). To test whether LAT phosphorylation induced by FcR clustering also occurs on
the tyrosine residues that promote binding of SH2 domain proteins, LAT
immunoprecipitates from resting and FcRI-activated THP-1 cells were
analyzed by Western blotting with anti-p85 (Fig.
4A, upper panel), anti-Grb2
(Fig. 4B, upper panel), anti-PLC1 (Fig. 4C),
and anti-SHIP antibodies. The data indicate that LAT inducibly associates with p85, Grb2, and PLC1 upon FcR clustering in THP-1 cells, as it does in T cells (25). In contrast no association of LAT
with SHIP was detected (data not shown). Thus, LAT may play a
functional role in transducing signals from FcR by associating with
and promoting membrane translocation of these signaling proteins.
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Fig. 4.
LAT associates with p85, Grb2, and
PLC upon FcR
clustering. THP-1 cells were activated for the indicated time
points by clustering FcRI. Cell lysates were immunoprecipitated with
anti-LAT antibody and analyzed by Western blotting with: A,
anti-p85; B, anti-Grb2; C, and anti-PLC1
antibodies. Control lanes analyze immunoprecipitations with normal
rabbit IgG. A whole cell lysate was loaded in the last lanes as a
positive control. The blots were subsequently reprobed with anti-LAT
antibody (lower panels).
RI- transfected COS-7
Cells--
FcRs bind to IgG-coated particles and mediate
phagocytosis. The signaling process accompanying phagocytosis involves
sequential activation of tyrosine kinases, and recruitment of PI
3-kinase to generate 3-phosphoinositides. These events promote actin
polymerization and cytoskeletal rearrangements such that the phagocyte
puts forth pseudopods to surround and engulf the particle (19, 35, 36). Recruitment of PI 3-kinase to the membrane has been shown to be both
necessary and sufficient for phagocytosis (21). Since LAT associates
with the p85 adapter subunit of PI 3-kinase, LAT could enhance
phagocytic efficiency of FcRs by promoting p85 recruitment and hence
activation of PI 3-kinase. To test this possibility we took advantage
of the COS cell model, which displays efficient phagocytosis upon
transfection with cDNA encoding FcRI plus the -subunit (32).
We first assessed the ability of transfected LAT to become tyrosine
phosphorylated upon FcR clustering in the COS cell model. Thus, COS
transfectants expressing FcRI, the -subunit, and/or Myc-tagged
wild-type or mutant (Y171F/Y191F) LAT, were activated for 3 min by
clustering FcRI receptors as described above. Phosphotyrosine
proteins were immunoprecipitated, separated by SDS-PAGE, and analyzed
by Western blotting with anti-LAT antibody (Fig.
5A). We observed that both
wild-type and LAT Y171F/Y191F are tyrosine phosphorylated by FcRI
clustering in COS transfectants and that this phosphorylation required
the presence of the -subunit. Tyrosine phosphorylation of the mutant
LAT is reduced compared with that of wild-type LAT, most likely since
two major tyrosines (Tyr171 and Tyr191) are
mutated to phenylalanine; other known phosphorylation sites are still
present in this mutant. These findings indicate that LAT becomes
tyrosine phosphorylated upon FcRI clustering in the COS cell model
in a -subunit dependent manner.
View larger version (40K):
[in a new window]
Fig. 5.
LAT enhances phagocytosis by
Fc RI in transfected COS-7 cells. COS-7
cells were transiently transfected to express the various proteins
indicated in the figure. A, lysates from resting or
FcRI-activated COS cells were immunoprecipitated with
anti-phosphotyrosine antibody and analyzed by Western blotting with
anti-LAT antibody. B, whole cell lysates from transfected
COS cells were separated by SDS-PAGE and analyzed by Western blotting
with anti-LAT antibody; or C, anti- subunit antibody.
D, COS-7 transfectants were tested for their ability to
phagocytose fluoresceinated IgG-coated SRBCs. For this, COS-7 cells
were incubated for 1 h with SRBCs, subjected to hypotonic lysis to
remove external SRBCs, and subsequently fixed and mounted on slides to
be analyzed by fluorescence microscopy. The number of SRBCs
internalized by 100 phagocytic cells was counted for each transfected
sample. The number of SRBCs ingested by COS cells transfected with
FcRI chain and the -subunit was considered as 100%. The
graph displays the mean and standard deviation of three separate
experiments. *, p value < 0.001.
1
(25), indicating that Tyr171 and Tyr191 are the
sites of SH2 engagement of LAT by these signaling enzymes. To measure
the phagocytic capacity of COS-7 transfectants, FcR and/or
LAT-transfected COS-7 cells were incubated with IgG-coated SRBCs for
1 h at either 4 or 37 °C, respectively. Mock transfected COS
cells were incubated with IgG-coated SRBCs to control for SRBC binding
unrelated to FcR expression, and all transfectants were also
incubated with fluoresceinated SRBCs that were not opsonized with IgG.
Binding efficiency was measured by counting the number of COS cells
that bound 3 or more SRBCs and expressed as "% Rosetting Activity"
(Table I). No binding of IgG-coated SRBCs
was observed with mock transfected cells (data not shown). Similarly
there was no binding of FcRI-transfected COS cells with
non-opsonized SRBCs, indicating that the binding observed was indeed
between the transfected Fc receptors and IgG (data not shown).
FcRI-mediated binding to opsonized SRBCs was not influenced by the
presence of any of the co-transfected molecules as indicated by the
rosetting activity of the various transfectants (Table I).
Influence of LAT on FcRI-mediated phagocytosis in COS-7
transfectants
RI chain,
-subunit ± LATwt or LATmut. FcRI expression in
transfectants was analyzed by flow cytometry, by first incubating the
cells with mAb 197, followed by FITC-labeled goat anti-mouse IgG
secondary antibody. Rosetting activity is the percentage of cells that
bound 3 or more SRBCs. Phagocytic index represents the number of SRBCs
ingested by 100 phagocytic cells. % 
is the deviation from the
"FcRI + " transfected cells that were considered to
display 100% phagocytic efficiency. The results of three separate
experiments are shown.
-subunit and the FcRI chain was comparable in all
transfectants, as determined by Western blotting and flow cytometry
respectively (Fig. 5C and Table I).
RI. To more rigorously address
this issue, we obtained bone marrow macrophages from wild type and LAT-deficient mice by culturing bone marrow cells in the presence of
colony stimulating factor-1 for 5 days. The resulting macrophages were
harvested and analyzed for the expression of FcRs. As seen in Fig.
6B, 99% of the BMMs from wild
type and LAT-deficient mice expressed FcRs as assessed by flow
cytometry using antibodies directed against FcRIII and FcRII
(2.4G2). We then tested the ability of wild type or LAT-deficient
macrophages to bind and ingest IgG-coated SRBCs by methods described
above. The results of two experiments performed with BMMs from separate
sets of mice are presented in Fig. 6A and indicate that IgG
binding is equivalent between wild type and LAT-deficient BMMs. Thus,
consistent with results using the COS-7 model, LAT expression does not
influence the affinity of FcRI. However, despite comparable
expression and affinity of FcRI expressed on wild type and
LAT-deficient BMMs, wild type BMMs were twice as efficient at
phagocytosing SRBCs as were the LAT-deficient BMMs. These data strongly
support a functional role for LAT in enhancing FcR-mediated
phagocytosis.
View larger version (18K):
[in a new window]
Fig. 6.
BMMs form LAT-deficient mice display reduced
phagocytic efficiency. A, BMMs from wild type and
LAT-deficient mice were examined for their ability to bind and ingest
IgG-coated SRBCs. Binding Index represents the total number
of SRBCs bound to 500 macrophages. Phagocytic Index
represents the number of SRBCs ingested by 500 macrophages. The graph
displays the average of two experiments performed with BMMs derived
from separate sets of mice. B, Fc R expression on the wild
type and LAT-deficient BMMs was analyzed by flow cytometry. For this,
the cells were labeled with anti-FcRII/III mAb 2.4G2 followed by
FITC-labeled goat anti-rat IgG secondary antibody (solid
line). Cells were also labeled with secondary antibody alone
(dashed line).
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
R-mediated signal transduction. Our results demonstrate that
LAT is expressed in myeloid cells, that LAT co-immunoprecipitates with
FcRI and FcRIIA in unactivated monocytes, and that LAT binds,
upon its tyrosine phosphorylation, with SH2 domain-containing signaling
proteins such as PLC1, Grb2, and p85. Furthermore, transient
transfection experiments in COS-7 cells demonstrated that
co-transfection of wild type but not Y171F/Y191F mutated LAT with the
FcR -subunit enhanced phagocytic efficiency. In addition, BMMs from
wild type mice displayed a 2-fold greater phagocytic efficiency than
those from LAT-deficient mice. Together, these findings suggest that
LAT serves to recruit signaling molecules to the plasma membrane and
thereby supports phagocytosis. While LAT is clearly not required for
phagocytosis, LAT may function in a synergistic manner with the FcR
ITAMs to elicit signaling events and phagocytosis.
R ITAMs, there is no identified mechanism thus far that accounts
for membrane recruitment of PLC1 or Grb2 in FcR-stimulated
myeloid cells. The association of phosphorylated LAT with PLC1 and
Grb2 in THP-1 cells suggests a role for LAT in these signaling
pathways. The Grb2 SH2 domain has been shown to associate directly with
phosphotyrosines in cytokine receptors that conform to a consensus YVNV
motif (37). Immunoreceptors do not bear a consensus motif for Grb2 SH2
binding and appear to associate with the Grb2-Sos complex via an
additional adapter protein, Shc (38, 39). However, LAT has five
potential tyrosine phosphorylation sites that fit a consensus binding
motif for Grb2 SH2. Absence of LAT expression or mutation of the
Grb2-binding sites in LAT completely abrogates the Ras/ERK pathway,
calcium mobilization, and interleukin-2 production in T cells (25, 28, 29). Based on these observations, the influence of LAT on
FcR-induced activation of Ras pathway may be much more profound than
the influence on PI 3-kinase-dependent biology. Studies are
underway to determine the role of LAT in Ras-dependent
biology of monocytes.
receptor in mast cells was reported to associate with lipid rafts upon FcR clustering (46, 47). Our results showing that FcRs
co-immunoprecipitate with LAT in both resting and activated
monocytes (Fig. 3) suggest that FcRs may similarly exist in lipid
rafts along with LAT and other important signaling molecules. Further
analysis is required to determine the location of FcRs in the plasma
membrane of myeloid cells.
R clustering and examined the role played by the adapter protein
LAT in facilitating FcR-induced signaling. The findings reveal an
additional mode by which FcRs relay signals to elicit biological
responses that contribute to innate immunity.
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed: The Ohio State
University College of Medicine, 2054 Davis Research Center, 480 W. 9th Ave., Columbus, OH 43210. Tel.: 614-293-4819; Fax:
614-293-4811; E-mail: anderson.48@osu.edu.
ABBREVIATIONS
R, Fc
-receptor;
LAT, linker for activation of T cells;
ITAM, immunoreceptor tyrosine based activation motif;
SH2, Src homology
domain 2;
PI 3-kinase, phosphatidylinositol 3-kinase;
ERK, extracellular signal-related kinase;
PLC1, phospholipase C 1;
BMM, bone marrow-derived macrophage;
TCR, T cell antigen receptor;
PBM, peripheral blood monocytes;
FITC, fluorescein isothiocyanate;
RBC, red
blood cell;
mAb, monoclonal antibody;
PAGE, polyacrylamide gel
electrophoresis;
SRBC, sheep red blood cell.
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