J Biol Chem, Vol. 274, Issue 34, 24349-24356, August 20, 1999
Immune Complex-induced Integrin Activation and L-plastin
Phosphorylation Require Protein Kinase A*
Jun
Wang
and
Eric J.
Brown§¶
From the Division of Infectious Diseases and Program
in Molecular Cell Biology, Washington University School of Medicine,
St. Louis, Missouri 63110 and § Program in Microbial
Pathogenesis and Host Defense, University of California,
San Francisco, California 94143
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ABSTRACT |
Integrins in resting leukocytes are poorly
adhesive, and cell activation is required to induce integrin-mediated
adhesion. We recently demonstrated a close correlation between
phosphorylation of Ser5 in L-plastin (LPL), a
leukocyte-specific 67-kDa actin bundling protein, and activation of
M
2-mediated adhesion in polymorphonuclear neutrophils (PMN) (Jones, S. L., Wang, J., Turck, C. W., and
Brown, E. J. (1998) Proc. Natl. Acad. Sci. U. S. A.
95, 9331-9336). However, the kinase that phosphorylates LPL
Ser5 has not been identified. We found that
cAMP-dependent protein kinase (PKA), but not a variety of
other serine kinases, can specifically phosphorylate LPL and
LPL-derived peptides on Ser5 in vitro. The
cell-permeable cAMP analog 8-bromo-cAMP and the adenylate cyclase
activator forskolin both induce LPL phosphorylation in cells. Two PKA
inhibitors, H89 and KT5720, inhibited immune complex (IC)-stimulated
LPL phosphorylation as well as IC-induced activation of
M2-mediated adhesion in PMN. The dose
response of H89 inhibition of PMN adhesion correlated with its
inhibition of LPL phosphorylation in response to IC. IC stimulation
also transiently increased intracellular cAMP concentration in PMN. Thus, PKA functions in an integrin activation pathway initiated by IC
binding to Fc
receptors in addition to its better known role as a
negative regulator of cell activation by G protein-coupled receptors.
In contrast, LPL Ser5 phosphorylation and PMN adhesion
induced by formylmethionyl-leucylphenylalanine or phorbol myristate
acetate were not affected by PKA inhibitors, suggesting that a
different kinase(s) is responsible for LPL phosphorylation in response
to these agonists. Phosphoinositidyl 3-kinase also is required for
FcR but not formylmethionyl-leucylphenylalanine- or phorbol
myristate acetate-induced LPL phosphorylation and activation of
M2. Two phosphoinositidyl 3-kinase
inhibitors blocked FcR-induced cAMP accumulation, demonstrating that
this kinase acts upstream of PKA. These data demonstrate a necessary
role for PKA in IC-induced integrin activation and LPL phosphorylation.
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INTRODUCTION |
Leukocyte integrins are able to modulate avidity for their
ligands. While circulating in blood or lymph, leukocytes maintain their
integrins in a low adhesive state. In contrast, when leukocytes migrate
out of the vasculature, their integrins have higher avidity, allowing
them to participate in the processes of extravasation and migration
through extracellular matrix. This regulation of integrin adhesion is
essential for appropriate leukocyte function, since integrin activation
is required for leukocyte migration to sites of inflammation and for
lymphocyte recirculation through lymph nodes, but inappropriate
activation leads to significant injury of normal tissues (1, 2). Many
molecules specifically found at inflammatory sites or in lymph nodes
can induce the transition of integrins from low to high avidity, and
exposure to these molecules provides the stimulus both for
transendothelial migration and for migration through the
extracellular matrix to sites of infection and inflammation (3, 4).
The molecular mechanisms that modulate integrin avidity are not well
understood. There is evidence for activation-induced increases in
integrin affinity (5-7), integrin clustering (8), and integrin
diffusion (9). At a molecular level, phosphoinositidyl 3-kinase (PI
3-kinase)1 (10), protein
kinase C (11, 12), and the Ca2+-dependent
protease calpain (13) all can have a role in leukocyte integrin
activation. In addition, there is evidence for involvement of the actin
cytoskeleton in regulation of integrin avidity (9, 14). We recently
demonstrated that cell-permeant peptides from the leukocyte-specific
actin bundling protein L-plastin (LPL) will activate myeloid
2 integrins (15). These studies showed that LPL
phosphorylation is closely associated with integrin activation and led
to the hypothesis that LPL phosphorylation is a necessary step for
integrin activation by many proinflammatory agents. This hypothesis has
focused attention on the unknown enzyme(s) that phosphorylate LPL.
A well studied mechanism for leukocyte integrin activation is exposure
to immune complexes (IC). IC binding to polymorphonuclear leukocyte
(PMN) IgG Fc receptors (FcR), especially FcRIIA, induces integrin
activation via a PI 3-kinase and PKC-dependent pathway, which is closely associated with LPL phosphorylation (12, 15). IC-induced activation of the leukocyte-specific integrin
M2 (Mac-1, CD11b/CD18) is required both
for sustained adhesion to IC in vitro (12, 16) and for a
normal IC-induced inflammatory response in vivo (17). Thus,
IC-induced M2 activation is probably a
critical event in antibody-dependent host defense against
infectious diseases as well as in idiopathic inflammatory diseases due
to autoantibodies. In the current study, we have used this model for
integrin activation to examine the hypothesis that LPL phosphorylation is an essential step in integrin activation. We show that the cAMP-dependent Ser/Thr kinase PKA phosphorylates LPL
in vitro on Ser5, the site of in vivo
phosphorylation, and that IC-induced LPL phosphorylation requires PKA.
Inhibition of PKA blocks sustained PMN adhesion to IC because
M2 activation is prevented. These data
not only support the hypothesis that LPL phosphorylation is a step in
leukocyte integrin activation but also show a surprising and unexpected
role in leukocyte activation for cAMP and PKA, generally considered to
be potent endogenous inhibitors of activation. Finally, PKA is not
required for LPL phosphorylation or integrin activation in response to
formylmethionyl-leucylphenylalanine (fMLP) or phorbol 12-myristate
13-acetate (PMA). Thus, there are at least two distinct signaling
pathways and kinases that lead to integrin activation through LPL
Ser5 phosphorylation.
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EXPERIMENTAL PROCEDURES |
Cells and Reagents--
Human PMN were isolated from the
peripheral blood of healthy donors by dextran sedimentation and
gradient centrifugation as described (18). Murine bone marrow PMN were
purified by Percoll density gradient as described (19). Cells were
resuspended in HBSS++ (1× Hanks' buffered salt solution
with 20 mM Hepes, 8.9 mM sodium bicarbonate,
1.0 mM Mg2+, and 1.0 mM
Ca2+) for all assays. A colony of CD18-deficient mice (a
gift of Dr. Art Beaudet, Baylor University, Houston, TX) and congenic
wild type or heterozygous mice were maintained as described previously (20). Jurkat T lymphoid cells (ATCC, Manassas, VA) were maintained in
RPMI 1640 medium (Life Technologies, Inc.) containing 10%
heat-inactivated fetal calf serum (Hyclone, Logan, UT), 2 mM L-glutamine, 0.1 mM nonessential
amino acids, 50 mM 2-mercaptoethanol, and 100 µg/ml penicillin and streptomycin under a 5% CO2 atmosphere.
F(ab)' fragments of IB4 (anti-CD18) were prepared as described (21). F(ab)' fragments of IV.3 (anti-CD32, anti-FcRII) and 3G8 (anti-CD16, anti-FcRIII) were purchased from Medarex, Inc. (Annandale, NJ). Recombinant cGMP-dependent protein kinase (PKG), protein
kinase C (PKC), casein kinase II, calmodulin-dependent
kinase II, H89, KT5720, 8-Br-cAMP, 8-Br-cGMP, forskolin, KN-62, and DRB
were from Calbiochem. Recombinant PKA was purchased from Sigma.
Recombinant LPL protein was purified from bacterial lysates using
immunoaffinity chromatography. Recombinant M2K (MAPKAPK2), M3K
(MAPKAPK3), and p38-regulated/activated protein kinase (22-24) were
the kind gift of Dr. Jiahuai Han (Scripps Research Institute, La Jolla,
CA). The sources of all other reagents have been described previously (12, 25).
LPL amino-terminal peptide and other mutant peptides were synthesized
in the Protein Chemistry Laboratory (Washington University, St. Louis,
MO). The following previously characterized peptides (15) were used in
this study: amino acids 2-19 of human LPL (ARGSVSDEEMMELREAFA), a
mutant peptide in which Ser5 has been changed to Ala (S5A)
(ARGAVSDEEMMELREAFA), a mutant peptide in which Ser7 has
been changed to Ala (S7A) (ARGSVADEEMMELREAFA), and a peptide in which
the 19 amino acids have been scrambled (SCR) (AGDESEMEFVMASALRRE).
Generation of Anti-phospho-LPL Antibody--
A polyclonal
anti-phospho-LPL antibody was generated against a peptide encoding LPL
amino acids 2-11 (ARGSVSDEEM) in which Ser5 was
phosphorylated. The serum from immunized rabbits was collected and
purified first by "negative" affinity on unphosphorylated peptide
and then "positive" affinity on the phosphorylated peptide by
Quality Controlled Biochemicals Inc. (Hopkinton, MA). Western blotting
with the affinity-purified antiserum demonstrated that the antibody
specifically recognized phosphorylated LPL from Jurkat cells as well as
PMN but not the unphosphorylated protein and that the selectivity to
phosphorylated LPL was similar to using autoradiography of LPL from
32P-loaded cells (Fig. 1).
This confirmed that in leukocytes Ser5 is a major LPL
phosphorylation site, as previously demonstrated by transfection of
HeLa cells (15).
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Fig. 1.
Anti-phospho-LPL antibody specifically
recognizes phosphorylated LPL. Data from experiments on
Jurkat cells (A) and PMN (B) are shown.
A, Jurkat cells were treated with the indicated
concentrations of 8-Br-cAMP. B, PMN were treated with buffer
control (lanes 1 and 3), H89
(lanes 2 and 4), or wortmannin
(lane 5) and then loaded to BSA- (lane
1) or IC- (lanes 3-5) coated surfaces
or activated with PMA (lane 2) in suspension. LPL
was immunoprecipitated as described under "Experimental
Procedures." LPL phosphorylation was detected by -32P
labeling (upper panel), or Western blotting with
anti-phospho-LPL antibody (middle panel).
Coomassie Blue staining of the two same gels showed equal loading of
total immunoprecipitated LPL protein (lower
panel).
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Adhesion Assay--
Tissue culture plates were coated with BSA,
BSA-anti-BSA IC, or fetal calf serum, and PMN were loaded with calcein
as described previously (12). PMN were treated with control buffer or
inhibitors for 30 min at 37 °C, following which 1 × 105 cells/well were added to BSA- or IC-coated wells and
incubated at 37 °C for the indicated times. For PMA- or
fMLP-stimulated adhesion, PMA (50 ng/ml final concentration), fMLP (0.5 µM final concentration), or Me2SO control was
added after the addition of cells to BSA-coated wells. After the
incubation period, the fluorescence (485-nm excitation and 530-nm
emission wavelengths) was measured using a fMax fluorescence plate
reader (Molecular Devices, Sunnyvale, CA) before and after washing four
times with 180 µl of phosphate-buffered saline. The percentage of
adhesion was calculated by dividing the fluorescence after washing by
the florescence before washing. In preliminary experiments,
fluorescence was shown to be linearly related to cell number.
In Vitro Phosphorylation Assay--
To assess peptide
phosphorylation, purified kinases were mixed with 100 µM
LPL, S5A, S7A, or SCR peptides in a reaction mixture containing 20 mM Tris, pH 7.4, 20 mM MgCl2, 10 mM dithiothreitol, 100 µM ATP, and
[-32P]ATP, incubated at 30 °C for 20 min. The
reaction mixtures were spotted onto P81 phosphocellulose paper and
washed four times in 75 mM phosphoric acid and once in 95%
ethanol, following which retained radioactivity was determined. For
in vitro LPL phosphorylation, 2.5 µg of purified
recombinant LPL protein was mixed with purified kinases in the reaction
mixture described above. After a 20-min incubation at 30 °C, the
reaction was stopped by the addition of 100 °C SDS-polyacrylamide
gel electrophoresis sample buffer, and protein components were resolved
on 10% SDS-polyacrylamide gel electrophoresis, transferred to
polyvinylidene difluoride membrane, and stained with Coomassie Blue to
assess the protein loading. The membrane was then subjected to
autoradiography to assess protein phosphorylation. Positive controls
for the activity of each kinase (substrate peptides for PKA, PKG, PKC,
and casein kinase II; myelin basic protein for Pak-1 and PKB; and
autophosphorylation for M2K, M3K, and p38-regulated/activated protein
kinase) were included in each assay to ensure that the kinase was
active against known substrates.
In Vivo LPL Phosphorylation--
Purified PMN or Jurkat cells
were loaded with 2 mCi/ml [32P]phosphoric acid for 2 h at 37 °C, washed once with HBSS, and resuspended in
HBSS++ with 0.1% human serum albumin. Cells were treated
with various inhibitors or buffer control and added to wells coated
with BSA or IC. Alternatively, PMA, fMLP, 8-Br-cAMP, 8-Br-cGMP, or
forskolin was added to cells in suspension. The cells were incubated at 37 °C for 30 min and lysed by adding 2 × lysis buffer (50 mM Tris 8.0, 1% deoxycholate, 1% Triton X-100, 150 mM NaCl, 100 mM NaF, 10 mM disodium
pyrophosphate, with the protease inhibitors 5 mM diisofluorophosphate, 1 mM phenylmethylsulfonyl fluoride, 5 µg/ml leupeptin, 5 µg/ml aprotinin) for 20 min on ice. The lysates
were centrifuged in a microcentrifuge at 14,000 rpm for 15 min at
4 °C. LPL was immunoprecipitated from the lysates with 2.5 µg of anti-LPL mAb LPL 4A.1 and 50 µl of a 1:1 slurry of goat anti-mouse Sepharose for 2 h at 4 °C. The immunoprecipitates were washed twice with 1× lysis buffer and twice with phosphate-buffered saline and 0.05% Tween 20 and then boiled in SDS sample buffer for 2 min. The
proteins were separated by SDS-polyacrylamide gel electrophoresis, transferred to polyvinylidene difluoride membrane, and stained with
Coomassie Blue to detect the total immunoprecipitated LPL protein. LPL
phosphorylation was detected by autoradiography. Alternatively,
phosphorylated LPL in nonradioactive cells was detected by Western
blotting immunoprecipitates with the anti-phospho-LPL antibody. In some
experiments, membranes were blotted with LPL 4A.1 (26) to detect total
phosphorylated and unphosphorylated LPL protein.
Determination of Intracellular cAMP--
1 × 106 PMN (in the presence of 100 µM
isobutylmethylxanthine) were treated with control buffer or inhibitors
and then added to IC- or BSA-coated 12-well TC plates and incubated for
the indicated times in a 37 °C water bath. After the incubation, the
cells were immediately centrifuged at 1200 rpm for 3 min at 4 °C.
Cell pellets were extracted with 65% (v/v) ice-cold ethanol. Cell
extracts were collected and cleared by centrifugation at 3000 rpm for
15 min at 4 °C. The supernatants were collected and dried in a
vacuum oven. The dried extract material was dissolved in assay buffer, and the content of cAMP was determined as described using the acetylation procedure with the cAMP EIA kit (Linco Research Inc., St.
Charles, MO) according to the manufacturer's directions.
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RESULTS |
cAMP-dependent Protein Kinase Specifically
Phosphorylates L-plastin on Ser5 in Vitro--
We have
determined that Ser5 is the predominant LPL phosphorylation
site (15). Since this serine is within a consensus sequence for
phosphorylation by the cAMP dependent protein kinase PKA (27), we
tested whether PKA could phosphorylate LPL. We found that the purified
catalytic domain of PKA phosphorylated an amino-terminal LPL peptide
(containing LPL amino acids 2-19) but not the peptide in which
Ser5 was mutated to Ala or a peptide in which LPL sequence
2-19 was scrambled (Fig. 2A).
Mutation of Ser7 to Ala as a control did not block PKA
phosphorylation (Fig. 2A). PKA also potently phosphorylated
whole recombinant LPL protein in vitro (Fig. 2B).
In contrast, PKG did not phosphorylate recombinant LPL (Fig.
2B) or LPL peptide (data not shown). While Ser5
also is within consensus sites for phosphorylation by PKC and casein
kinase II, neither the catalytic domain of PKC nor casein kinase II
phosphorylated LPL peptides or recombinant LPL protein in
vitro (data not shown). In addition, we have tested Pak1, protein kinase B, and some downstream kinases in the mitogen-activated protein
kinase pathway, such as M2K (MAPKAPK2), M3K (MAPKAPK3), and
p38-regulated/activated protein kinase (22-24); all failed to
phosphorylate LPL or its amino-terminal peptide in vitro
(Ref. 15 and data not shown). Thus, in contrast to other candidate kinases, PKA can specifically phosphorylate LPL on Ser5
in vitro.
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Fig. 2.
cAMP-dependent protein kinase
specifically phosphorylates L-plastin on Ser5 in
vitro. A, PKA catalytic domain
phosphorylation of LPL peptide 2-19 (LPL), the same peptide in which
Ser5 was replaced by Ala (S5A), the LPL peptide in which
Ser7 was changed to Ala (S7A), and a scrambled LPL peptide
(SCR) was examined as described under "Experimental Procedures." As
negative controls, reaction mixtures were prepared without peptide
substrate (no pep) or without kinase (no kinase).
B, purified recombinant LPL was incubated with
[-32P]ATP and PKA or PKG as described under
"Experimental Procedures." LPL phosphorylation was analyzed by
autoradiography (32P) as described in Fig. 1. Total loading
of LPL was assessed by Coomassie Blue staining. The identity of the
70-kDa band in the PKG lanes is unknown, but it
was in the recombinant PKG preparation.
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PKA Activators Cause LPL Phosphorylation in Vivo--
To examine
whether PKA is involved in LPL phosphorylation in vivo, we
tested the effects on LPL phosphorylation of the PKA activators
8-Br-cAMP, a cell-permeable cAMP analog (Fig.
3A), and forskolin, an
adenylate cyclase activator (Fig. 3C). Both induced LPL
phosphorylation in a dose-dependent fashion in Jurkat cells. In contrast, the cell-permeant cGMP analog 8-Br-cGMP did not
induce LPL phosphorylation even at 5 mM (data not shown). The increased LPL phosphorylation induced by 8-Br-cAMP or forskolin was
readily inhibited by the PKA-specific inhibitor H89 (Fig. 3,
B and C). 8-Br-cAMP also induced LPL
phosphorylation in PMN, but only at a concentration of 5 mM
(data not shown). Thus, PKA can directly phosphorylate LPL in
vitro, and pharmacologic PKA activation can induce LPL
phosphorylation in intact cells.
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Fig. 3.
PKA activators cause LPL phosphorylation,
which is inhibited by the PKA-specific inhibitor H89.
A, Jurkat cells were loaded with
[32P]phosphoric acid prior to treatment with the
indicated concentration of 8-Br-cAMP for 30 min at 37 °C. LPL
phosphorylation was assessed by autoradiography; LPL loading was
assessed by Coomassie Blue staining. B, Jurkat cells were
treated with various concentrations of H89 as indicated for 30 min at
37 °C and then incubated with 1 mM 8-Br-cAMP or buffer
for an additional 30 min. LPL phosphorylation was detected by Western
blotting with the anti-phospho-LPL antibody as described in Fig. 1. LPL
loading was assessed by Coomassie Blue staining. C, same as
B, except that cells were treated with the indicated
concentrations of forskolin.
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PKA Inhibitors Prevent IC Induction of LPL
Phosphorylation--
cAMP has most frequently been found to inhibit
PMN activation (28-30), while LPL phosphorylation has been associated
with PMN integrin activation (15). To investigate the potential
significance of PKA in agonist-activated LPL phosphorylation, the
effects of two PKA inhibitors, H89 (31) and KT5720 (32), were tested on
LPL phosphorylation induced by IC, fMLP, or PMA. Both H89 and KT5720
potently inhibited LPL phosphorylation initiated by IC ligation of
Fc receptors in PMN (Fig. 4,
A and B). Neither the casein kinase II inhibitor
5,6-dichloro-1--D-ribofuranosylbenzimidazole (33) nor
the CaM kinase II inhibitor KN-62 (34) inhibited IC-induced LPL
phosphorylation, demonstrating specificity of the effects of these two
structurally unrelated PKA inhibitors. Moreover, neither PMA nor fMLP
activation of LPL phosphorylation was inhibited by H89 or KT5720 (Fig.
4C and data not shown). These results suggest that PKA is
responsible for IC-induced LPL phosphorylation in PMN but is probably
not the kinase that phosphorylates LPL Ser5 in response to
fMLP or PMA.
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Fig. 4.
H89 inhibits IC-, but not PMA- or
fMLP-activated LPL phosphorylation. A, purified human
PMN were loaded with [32P]phosphoric acid, treated for 30 min with 5,6-dichloro-1--D-ribofuranosylbenzimidazole
(DRB; 100 µM), H89 (50 µM),
KN-62 (100 µM), or Me2SO (DMSO) as
control prior to incubation on BSA- or IC-coated surfaces as described
under "Experimental Procedures." LPL phosphorylation was assessed
by autoradiography. B, PMN were treated with KT5720 (5 µM) or Me2SO prior to incubation on BSA- or
IC-coated surfaces. LPL phosphorylation was assessed by immunoblotting
with anti-phospho-LPL Ab. The loading of total LPL was assessed by
immunoblotting the same membrane with LPL4A.1. C, PMN were
treated with H89 (50 µM) or control and then left
unstimulated or stimulated with fMLP (500 nM) or PMA (50 ng/ml) for 10 min. LPL phosphorylation was assessed by Western
blot.
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PKA Is Required for Sustained PMN Adhesion to an IC-coated Surface,
but Not for PMA- or fMLP-activated Adhesion--
Previous data suggest
that LPL phosphorylation precedes M2
activation, since IC, PMA, and fMLP all induce phosphorylation normally
in the absence of expression of M2 (25).
Cell-permeant peptides containing the Ser5 phosphorylation
site or constitutively phosphorylated Ser5 activate
M2, suggesting a role for LPL
phosphorylation in integrin activation. To assess the relevance of LPL
phosphorylation by PKA for integrin activation, we investigated the
effects of PKA inhibitors on activation of
M2-mediated adhesion in PMN. While initial adhesion of PMN to an IC-coated surface requires only Fc
receptors, sustained adhesion requires activation of
M2 (12, 16). H89 inhibited IC-induced
adhesion significantly at a late time point (30 min) but had no effect
on early PMN attachment (Fig.
5A), which is identical to the
defect of 2-deficient PMN (16). The kinetics of
attachment to IC by H89-treated PMN parallel those of
wortmannin-treated PMN (Fig. 5A), which fail to activate M2 in response to FcgR ligation (12).
Thus, like wortmannin (12), H89 specifically blocked
M2 activation by IC. Both H89 and
wortmannin blocked IC-induced LPL phosphorylation (Fig. 5A, inset, Fig. 4, and Ref. 15). Furthermore, the dose response of H89 inhibition of LPL phosphorylation correlated closely to the
inhibition of sustained IC-induced adhesion (Fig. 5B),
consistent with the hypothesis that PKA phosphorylation of LPL is a
required step in IC-induced activation of
M2. In contrast, neither H89 nor KT5720
inhibited fMLP or PMA activation of PMN
M2-mediated adhesion (Fig. 5,
C and D). In fact, H89 or KT5720 moderately increased both control and fMLP-induced adhesion to BSA or fetal calf
serum-coated surfaces (Fig. 5, C and D, and data
not shown), in agreement with previous studies demonstrating that cAMP
inhibits fMLP-induced PMN activation (35-39). Thus, H89 and KT5720
inhibition of sustained PMN adhesion to IC was not due to nonspecific
toxic effects of these pharmacologic agents but rather to inhibition of
FcR initiated signal transduction. These results indicate that PKA
plays a positive role in IC-initiated PMN adhesion, perhaps via
phosphorylation of LPL.
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Fig. 5.
PKA inhibitors block PMN adhesion to
IC-coated surfaces but have no effect on PMA- or
fMLP-activated adhesion. A, purified human PMN were
treated with H89 (50 µM), wortmannin (100 nM), or buffer prior to incubation on BSA- or IC-coated
surfaces for the indicated times at 37 °C.  , BSA;  , IC;  ,
IC plus H89;  , IC plus wortmannin. The data are the mean ± S.E. of triplicate wells, reported as the percentage of added cells
that remain adherent after washing. Inset, a portion of
cells at the 30-min time point were taken, and LPL phosphorylation was
assessed as described under "Experimental Procedures."
B, left, PMN were treated with varying
concentrations of H89 and allowed to adhere for 30 min to BSA- or
IC-coated surfaces, and LPL phosphorylation was measured.
Right, PMN were treated identically to those in the
left panel, and adhesion assays were performed as
described under "Experimental Procedures." The dotted
line represents the quantitation of the density of each band
in the left panel (except the BSA band, which was
not included). , BSA; , IC;  , LPL phosphorylation.
C, PMN, preincubated with H89 (open
bars; 50 µM) or buffer (filled
bars), were incubated with BSA-coated surfaces with PMA (50 ng/ml), fMLP (500 nM), or buffer. Adhesion was quantitated
as above. D, same as C except that cells were
treated with KT5720 (filled bars; 5 µM) or Me2SO (DMSO; open
bars) control. The data in each panel are
representative of at least three independent experiments.
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PKA Is Required for Fc Receptor-induced
M2 Integrin Activation--
The time
course of H89 inhibition of IC-induced adhesion (Fig. 5A)
showed that H89 did not inhibit early adhesion but completely inhibited
adhesion after 30 min, indicating that PKA probably has no role in
FcR-mediated initial adhesion but is involved in activation of
M2 by FcR ligation. To further test
this hypothesis, we examined the effects of PKA inhibitor H89 on
IC-induced adhesion in PMN from mice with 2 integrin
deficiency due to gene disruption by a neomycin cassette (20).
2 integrin-deficient PMN can only adhere to IC for a
short period of time and then fall off because M2 is required for sustained adhesion to
IC (16, 17). In murine PMN (mPMN), even early FcR-mediated adhesion
is dependent on M2. Therefore,
2 integrin-deficient mPMN adhere to IC less well than
wild type even in early time points. Nonetheless, 2 integrin-deficient mPMN adhered specifically to IC. Adhesion was transient and disappeared after 30-40 min (Fig.
6A). H89 had no effect on
adhesion of these mPMN to IC but inhibited sustained adhesion in wild
type mPMN, as it had in human PMN (Fig. 6, A and
B). Adhesion of H89-treated wild type mPMN was reduced to the level of 2 integrin-deficient mPMN (Fig.
6B). These results prove that PKA is not required for
initial FcR-mediated adhesion but is necessary for FcR-induced
M2 integrin activation.
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Fig. 6.
Adhesion of murine PMN to IC.
A, bone marrow PMN from 2 integrin-deficient
mice (2 / mPMN) were allowed to adhere to
BSA- or IC-coated surfaces in the presence of increasing concentrations
of H89. Cell adhesion was quantitated as described under
"Experimental Procedures."  , BSA;  , IC; , IC plus H89 (25 µM); , IC plus H89 (50 µM).
B, adhesion to IC of 2/ and
wild type mPMN was compared in the absence and presence of H89. Cell
adhesion was quantitated as above. The data are from one of three
independent experiments with similar results. , wild type plus
buffer; , wild type plus H89 (25 µM); ,
2/ plus buffer; ,
2/ plus H89 (25 µM); ,
wild type plus H89 (50 µM).
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Ligation of Fc Receptors Transiently Increases Intracellular
cAMP Level in PMN--
To determine whether IC-induced activation of
PKA resulted from an increase in intracytoplasmic cAMP concentration
([cAMP]), cytoplasmic [cAMP] was measured at various times after IC
activation. [cAMP] was transiently increased when PMN adhered to IC,
with a peak at 5 min, and then returned to its initial level after 15 min (Fig. 7A). The increase in
cAMP was inhibited by anti-FcRII antibody IV.3, confirming its
initiation by IC ligation of FcRs. As expected, PKA inhibitor H89 or
anti-2 antibody IB4 treatment did not inhibit this
increased cAMP level (Fig. 7B), demonstrating that cAMP
elevation requires FcRIIA ligation but precedes PKA and integrin
activation.
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Fig. 7.
IC adhesion transiently increases
intracellular cAMP in PMN. A, PMN were treated with
wortmannin (100 nM) or LY294002 (25 µM) or
Me2SO control for 15 min and then allowed to adhere to
surfaces coated with BSA or IC for the indicated times. [cAMP] was
determined as described under "Experimental Procedures." Each point
represents the average of duplicates. , BSA; , IC; , IC plus
wortmannin;  , IC plus LY294002. B, PMN were pretreated
with F(ab)' of IV.3 anti-FcRII (20 µg/ml), F(ab)' of IB4
anti-2 (20 µg/ml), H89 (50 µM), or
buffer and allowed to adhere to BSA- or IC-coated surfaces. [cAMP] in
each sample was determined after 5 min. The data are representative of
three independent experiments.
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Since PI 3-kinase inhibitors blocked sustained adhesion to IC with
similar kinetics as PKA inhibitors and also blocked LPL phosphorylation
(Fig. 5A and Refs. 12 and 15), it was important to determine
whether PI 3-kinase is necessary for PKA activation by IC. Both
wortmannin and LY294002, two PI 3-kinase inhibitors with
different modes of action, blocked IC-induced increase in cAMP (Fig.
7A), suggesting that PI 3-kinase functions upstream of PKA
in the pathway for LPL phosphorylation and integrin activation, perhaps in regulation of adenylate cyclase.
| |
DISCUSSION |
Previous work using cell-permeant peptides from the amino terminus
of LPL showed that these peptides were capable of inducing rapid
integrin activation in PMN (15). Integrin activation by these peptides
required Ser5 and was prevented by PI 3-kinase inhibitors.
Surprisingly, integrin activation by a cell-permeant peptide in which
Ser5 was phosphorylated was independent of PI 3-kinase,
leading to the hypothesis that the well described role for PI 3-kinase
in integrin activation (10) results from its involvement in a pathway resulting in phosphorylation of Ser5 of LPL. These studies
focused attention on the phosphorylation of LPL Ser5 as a
potentially critical regulatory step in activation of PMN integrins. In
the present work, we present data indicating that PKA can phosphorylate
LPL and does so when PMN FcRIIA is ligated. First, PKA
phosphorylates both LPL and an LPL amino-terminal peptide in
vitro. PKA phosphorylation occurs on Ser5, as
determined by failure of phosphorylation of the S5A mutant peptide and
by recognition of PKA-phosphorylated LPL by a
phospho-Ser5-specific antibody. Second, agents that
increase intracytoplasmic [cAMP], which activates PKA, induce LPL
phosphorylation. Finally, two pharmacologic PKA inhibitors block
IC-induced LPL phosphorylation in PMN. While the data in whole cells
demonstrate only that PKA activation can lead to LPL phosphorylation,
together with the demonstration of direct phosphorylation in
vitro, these data support the hypothesis that PKA can directly
phosphorylate LPL in cells. It is likely that other kinase(s) can
phosphorylate LPL as well, since fMLP and PMA-induced phosphorylation
are not antagonized by the same PKA inhibitors that block IC-induced
phosphorylation. While these kinases are not known, PKC is not a likely
candidate, since neither recombinant LPL nor the LPL amino-terminal
peptide was phosphorylated by the PKC catalytic domain in
vitro. The existence of distinct kinases that can phosphorylate
LPL is consistent with previous data suggesting two distinct signaling
pathways for both LPL phosphorylation and integrin activation (12,
15).
The hypothesis that LPL phosphorylation is a requisite step in PMN
integrin activation suggests that interference with its phosphorylation
should block activation-dependent integrin-mediated adhesion. Since PKA inhibitors blocked LPL phosphorylation by IC, we
tested the effects of these inhibitors on
M2 integrin activation by examining
sustained adhesion to IC. These inhibitors blocked IC-induced,
M2-dependent sustained
adhesion of both human and murine PMN. The specificity of the effect
was demonstrated by (i) failure of inhibitors of other serine kinases
to affect M2 activation; (ii) failure of
the PKA inhibitors to affect the transient FcR-mediated adhesion to
IC that occurs in M2-deficient PMN; and
(iii) failure of the PKA inhibitors to block
M2-mediated adhesion induced by fMLP and
PMA, which cause PKA-independent LPL phosphorylation. Thus, these data
are further evidence for a close association between LPL
phosphorylation and PMN integrin activation and support the hypothesis
that LPL phosphorylation (which occurs normally in
M2-deficient cells (25)) is a required step in activation of M2-mediated adhesion.
A role for cAMP in phagocyte activation is quite unexpected. In
general, increases in [cAMP] have been found to inhibit
fMLP-stimulated PMN activation, as measured by adhesion or respiratory
burst activation (30, 36, 40, 41) and have been found to inhibit
integrin activation in several cell types (29, 42, 43). However, FcR-mediated accumulation of cAMP and of PKA at phagosomes has been
noted previously (44, 45), although this cAMP has been variously
interpreted as part of the activation process (44) and a component of
the regulation of phagocytosis (45). A resolution of the apparent
conflict between the well described negative regulatory role for cAMP
in fMLP stimulation and its activating role in FcR-mediated signaling may lie in the compartmentalization of cAMP in response to
FcR ligation. Localized increases in cAMP may be prevented from
propagating through the cytoplasm by the colocalization of phosphodiesterase (45), and it is of note that in the present study
increases in cytosolic [cAMP] on adhesion to IC could only be
detected in the presence of a phosphodiesterase inhibitor. Pharmacologic increases in cAMP or increases that occur because of
ligation of receptors (28) at a distance from the adhesion site may
activate quite different processes than cAMP confined to the region of
FcR ligation, because of access to different downstream signaling
pathways. In this regard, it is potentially interesting that LPL is
phosphorylated by 8-bromo-cAMP addition in PMN only at very high
concentrations, consistent with the possibility of divergent effects of
this mediator on the different pathways leading to LPL phosphorylation.
Nonetheless, LPL phosphorylation by high concentration 8-Br-cAMP in the
absence of M2 activation suggests that
LPL phosphorylation is not sufficient for integrin activation.
Finally, our data suggest that PI 3-kinase is involved in an
FcR-initiated pathway to PKA activation, since wortmannin and LY294002 both block PKA-mediated LPL phosphorylation in PMN and FcR-induced increase in [cAMP]. Activation of PI 3-kinase by PMN
FcR ligation is well described (46-48), and inhibition of PI
3-kinase has been shown to block FcR-mediated phagocytosis (47), LPL
phosphorylation, and integrin activation (12, 15). Our data demonstrate
that PI 3-kinase inhibitors block FcR-induced cAMP accumulation,
which is consistent with the hypothesis that the role for PI 3-kinase
is upstream of PKA activation in IC-induced integrin activation. While
this could theoretically be either through regulation of adenylate
cyclase or phosphodiesterase activity, the PI 3-kinase inhibitors
blocked cAMP accumulation when phosphodiesterase activity was inhibited
by isobutylmethylxanthine, strongly implicating PI 3-kinase in
activation of adenylate cyclase. While the signaling pathway
responsible for this regulation is unknown, there is evidence that the
state of assembly of the actin cytoskeleton, which can be regulated by
PI 3-kinase, affects adenylate cyclase activity in S49 cells (49) and
in yeast (50, 51). It is intriguing as well that an adenylate cyclase
regulatory protein in Dictyostelium contains a pleckstrin
homology domain (52), since these domains often bind inositol
1,4,5-trisphosphate, the product of PI 3-kinase activity. Whatever the
precise mechanism, these studies have identified adenylate cyclase as a
physiologically significant downstream target of PI 3-kinase after its
activation by FcR ligation.
In summary, this work has two significant implications for
understanding the biochemical pathways that lead to PMN integrin activation. First, these studies identify a PKA-dependent
activation pathway initiated by IC. Although PKA has generally been
thought to negatively regulate PMN activation, most of these studies
have been done primarily with fMLP-induced activation, and the current data are completely compatible with the previously observed divergence between IC- and fMLP-induced PMN activation (12). Furthermore, IC-initiated PKA activation is dependent on PI 3-kinase via its regulation of adenylate cyclase, a novel pathway for regulation of
cytoplasmic [cAMP].
Second, these data support the hypothesis that LPL phosphorylation is a
requisite step in PMN integrin activation. PKA inhibitors block
IC-induced integrin activation but not fMLP- or PMA-induced activation,
which is in perfect accord with their effects on LPL phosphorylation.
Since PKA was identified as a candidate for involvement in integrin
activation because of its ability to phosphorylate LPL in
vitro, these data strongly support the involvement of LPL phosphorylation in integrin activation. While additional methods of
approach will be required to define the mechanism by which LPL
phosphorylation affects integrin function, it is highly likely that
this is a significant regulatory step in the regulation of leukocyte
integrin avidity.
| |
FOOTNOTES |
*
This work was supported by Grant AI35811 from the National
Institutes of Health (to E. J. B.).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.
¶
To whom correspondence can be addressed: University of
California, San Francisco, HSE 201, Campus Box 0513, 513 Parnassus Ave., San Francisco, CA 94143. Tel.: 415-514-0167; Fax: 415-514-0169; E-mail: ebrown@medicine.ucsf.edu.
| |
ABBREVIATIONS |
The abbreviations used are:
PI 3-kinase, phosphatidylinositol 3-kinase;
FcR, receptor for the Fc piece of
IgG;
fMLP, formylmethionyl-leucylphenylalanine;
IC, immune complex(es);
LPL, L-plastin;
PKA, cAMP-dependent protein kinase A;
PKG, cGMP-dependent protein kinase G;
PMA, phorbol 12-myristate
13-acetate;
PMN, polymorphonuclear neutrophil(s);
mPMN, murine PMN;
S5A, synthetic peptide based on amino acids 2-19 of LPL in which
Ser5 has been changed to Ala;
S7A, synthetic peptide based
on amino acids 2-19 of LPL in which Ser7 has been changed
to Ala;
SCR, synthetic peptide in which amino acids 2-19 of LPL have
been scrambled;
PKC, protein kinase C;
8-Br-cAMP and -cGMP, 8-bromo-cyclic AMP and GMP, respectively;
HBSS, Hanks' balanced salt
solution;
BSA, bovine serum albumin.
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ABSTRACT
INTRODUCTION
