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J. Biol. Chem., Vol. 277, Issue 19, 16371-16375, May 10, 2002
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From the
Received for publication, February 6, 2002
Chemokines modulate leukocyte integrin avidity to
coordinate adhesion and subsequent transendothelial migration, although the sequential signaling pathways involved remain poorly characterized. Here we show that integrin-linked kinase (ILK), a 59-kDa
serine-threonine protein kinase that interacts principally with
Current models of leukocyte accumulation from the
vasculature suggest that the process occurs through a series of
sequential steps (1). The selectin family (E-, P-, and L-selectin) of adhesion molecules predominantly governs the initial rolling
interaction between leukocytes and vascular endothelium. Subsequent
firm arrest occurs via leukocyte integrin interactions with endothelial
immunoglobulin superfamily members, such as vascular cell adhesion
molecule-1 (VCAM-1).1
Chemokines enhance leukocyte accumulation by the rapid conversion of
initial leukocyte tethering to firm adhesion. After leukocyte arrest,
chemokines then drive transendothelial migration of leukocytes into the
surrounding tissues.
Specific chemokines including monocyte inflammatory protein Here we investigated the role of integrin-linked kinase in
chemokine-triggered signaling. ILK was originally identified in a
search for proteins capable of interacting with Based on evidence that ILK is associated with Materials--
RPMI 1640 medium, Dulbecco's modified Eagle's
medium, and Dulbecco's phosphate-buffered saline with or
without Ca2+ and Mg2+ were purchased from
BioWhittaker, Inc. Fetal bovine serum was obtained from Hyclone Inc.
Recombinant MCP-1, interleukin 8, and sVCAM-1 were purchased from R&D
Systems. Biochemical inhibitors wortmannin and LY294002 were obtained
from Alexis Corp.
Cell Culture--
HEK 293 cells were obtained from
American Type Culture Collection and cultured in Dulbecco's modified
Eagle's medium supplemented with 10% fetal bovine serum. Human
umbilical vein endothelial cells (HUVECs) were isolated and cultured in
M199 with 20% fetal bovine serum, endothelial cell growth factor (25 µg/ml; Biomedical Technologies, Stoughton, MA), porcine intestinal
heparin (50 µg/ml; Sigma), and antibiotics. After infection with
adenoviral vectors, HUVECs were cultured as described above, but the
serum concentration was reduced to 10%. For experimental use in the
flow plate apparatus, HUVECs (passage 1-2) were plated at confluence
in 0.5-cm2 chambers on fibronectin-coated plastic tissue
culture slides. On the day of the flow adhesion assay, a fluorescence
immunoassay was performed on HUVECs infected in parallel to document
transgene expression and to rule out nonspecific activation of the
endothelial monolayer, as described previously (9). THP-1 cells were
obtained from American Type Culture Collection. Cells (1 × 107) were infected at an MOI of 10-50 in 0.5 ml of
serum-free RPMI 1640 medium in a 12-well dish for 2 h, and the
volume was subsequently increased to 2.0 ml, and serum was added to
reach 10%. Experiments were performed, and transgene expression was
evaluated 24 h after infection.
ILK cDNA Constructs--
The wild-type (WT) and
kinase-deficient (KD) ILK constructs were generated in the laboratory
of Dr. Shoukat Dedhar (University of British Columbia) (3, 5). These
constructs encode a V5 epitope tag.
Recombinant Adenoviruses--
The adenoviruses carrying the
adhesion molecules E-selectin (AdE-sel) and VCAM-1 (AdVCAM-1) as well
as the adenoviral control (AdEGFP) have been described previously
(9-11). ILK WT and KD adenoviruses were prepared via recombination in
Escherichia coli as described by He et al. (12).
Briefly, constructs were subcloned into the shuttle vector
pAdTrack-CMV, and homologous recombination was performed in E. coli with the pAdEasy-1 adenoviral backbone plasmid. Recombinants
were selected for kanamycin resistance, and recombination was confirmed
by restriction endonuclease analysis and PCR. The adenovirus packaging
cell line (HEK 293) was transfected with recombinants, and lysates were
analyzed by Western blotting. After screening for expression of the
appropriate transgene, adenoviruses were then prepared as high-titer
stocks. Stocks were titered in plaque assays on 293 cells, and
wild-type adenovirus contamination was excluded by the absence of
PCR-detectable E1 sequences.
Antibodies--
Signaling molecules were ILK (Upstate
Biotechnology), phospho-GSK-3 Flow Cytometry--
Monocytes were washed once with RPMI 1640 medium/5% fetal calf serum, incubated with the indicated
fluorescence-tagged (non-fluorescein isothiocyanate for EGFP-transduced
cells) primary antibodies for 30-60 min on ice, washed twice with RPMI
1640 medium/5% fetal calf serum, and fixed with 1% formaldehyde. An
isotype-matched, fluorescence-labeled, nonbinding antibody was included
as a control. Fluorescence was then analyzed using a BD PharMingen
fluorescence-activated cell sorter set to detect fluorescence, forward
scatter, and size.
Leukocyte Isolation--
Human leukocyte subsets were purified
from healthy human donors by Ficoll-Hypaque density gradient
centrifugation at 15 °C (LSM; Organon Teknika, Durham, NC).
Neutrophils were purified from the lower fraction after dextran
sedimentation and hypotonic lysis of red cells. Monocytes or
lymphocytes were purified from the mononuclear band by magnetic bead
purification, using a negative selection strategy (monocyte and
lymphocyte isolation kits; Miltenyi Biotech) (11). Leukocyte subset
suspensions were consistently >92% pure as determined by light
scatter and cell surface antigen analysis.
Adhesion Assays under Flow--
We employed a commercially
available parallel plate laminar flow chamber (Immunetics, Cambridge,
MA) (11, 17). For biochemical inhibitor studies, the monocytes were
incubated with the indicated compound or vehicle (Me2SO)
for 30 min at 37 °C and then diluted with perfusion media to
106 cells/ml. Where indicated, chemokines were added to the
monocyte reservoir (room temperature). Monocyte firm adhesion (>3 s)
was quantified for each coverslip 1 min before and 1 min after the addition of the chemokine. The cells were perfused at an estimated shear stress of 2.0 dynes/cm2 (flow rate, 0.78 ml/min). The
entire period of perfusion was recorded on videotape.
ILK Activity--
Human monocytic THP-1 cells or freshly
isolated primary human leukocyte subsets were left untreated or
stimulated with 100 nM human MCP-1 at 37 °C for the
indicated time periods. Cells were lysed in an ice-cold buffer
containing 150 mM NaCl, 50 mM Tris·HCl, pH
7.6, 1% Triton X-100, 1 mM sodium orthovanadate, and 4 µM microcystein in the presence of protease inhibitors
(Roche Molecular Biochemicals). Precleared cell lysates were incubated with a polyclonal anti-ILK antibody (Upstate Biotechnology) and protein
A beads overnight at 4 °C. Immune complexes were washed twice with
lysis buffer followed by two washes with 1 ml of kinase buffer
containing 150 mM NaCl, 25 mM Tris, pH 7.5, 5 mM Statistical Analysis--
Data are expressed as the mean ± S.D. Statistical comparison of means was performed by two-tailed
unpaired Student's t test. The null hypothesis was rejected
at p < 0.05.
ILK Is Expressed in Human Mononuclear Cells--
ILK expression
has been documented by mRNA and protein analysis in a variety of
cell types and tissues, including heart, skeletal muscle, kidney, and
pancreas (3). We first performed Western analysis to examine whether
ILK protein is expressed in purified human leukocyte subsets. As seen
in Fig. 1, human whole peripheral blood
mononuclear cells, specifically the monocyte and T-cell subsets,
prominently expressed the 59-kDa ILK protein. In contrast, resting
human neutrophils appeared to have no ILK.
Chemokines Activate ILK--
In light of the association of ILK
and
Chemokines activate several PI3K isoforms in leukocytes. These include
the "classical" PI3K- ILK Activation Inhibits
We performed flow cytometry experiments on transduced monocytic cells
in parallel with biochemical and functional assays. We saw no effect of
adenoviral gene transfer of control or ILK constructs on surface
expression of The emigration of circulating blood leukocytes into subendothelial
tissues involves multiple steps. Leukocyte firm attachment and
transendothelial migration are mediated by integrins, immunoglobulin superfamily members, matrix proteins, and chemokines. The signaling processes by which chemokines dynamically modulate integrins to orchestrate leukocyte adhesion and cell release are poorly understood.
Integrin-linked kinase is a focal adhesion serine-threonine kinase
associated principally with These data are consistent with a growing body of evidence associating
ILK with integrin-triggered signaling ("outside-in signaling") as
well as intracellular signaling cascades that culminate in integrin
activation ("inside-out signaling") (25). In other systems,
epithelial cell adhesion to matrix proteins triggers ILK activation
(3). Consistent with these prior findings, leukocyte adhesion to VCAM-1
also activated ILK in our studies. Interestingly, however,
MCP-1-triggered activation far exceeded that seen upon leukocyte-matrix interactions.
PI3K is a key intermediary in cell motility, specifically in
chemokine-triggered leukocyte recruitment (11, 26-28). The obligate pathways downstream of PI3K remain poorly understood (23, 29). Very
recent investigation in fibroblasts suggests a role for ILK in shape
change and motility (6). However, the relevant cellular ligands remain
undefined. The present work therefore extends prior studies because it
implicates members of the chemokine superfamily as potent agonists of
ILK in a PI3K-dependent cascade modulating leukocyte adhesion.
Our functional data suggest that ILK may play a role in the sequential
modulation of integrin affinity and avidity, which has been proposed as
a crucial mechanism to facilitate leukocyte adhesion and
transendothelial migration (2). CC chemokines such as MCP-1
transiently increase and then subsequently reduce VLA-4-mediated
binding of monocytes to VCAM-1 (2), and these data suggest a role for
ILK in the latter process. Because ILK negatively modulates
Rapid pulses of stimuli, such as those seen with chemokine stimulation,
may be important for activating the specific signaling pathways that
coordinate cell adhesion and migration. A limitation of the present
studies in evaluating a physiological role for ILK in leukocyte
recruitment is the persistent signal conferred by the adenoviral
constructs. We recognize that a number of potentially confounding
pathways could be activated by persistent ILK stimulation in our
studies. Newer systems that employ small molecule agonists of chimeric
proteins turned on in seconds or minutes (31) or transgenic animals
alluded to above will be helpful to further dissect a role for ILK in
leukocyte recruitment.
Our working model suggests that chemokines such as MCP-1 can convert
initial monocyte tethering to firm arrest following a brief,
potentially subsecond exposure (17, 32). Once the leukocyte has engaged
the endothelium, ILK activation persists over several minutes.
Sustained ILK activation, in turn, may represent a counter-regulatory mechanism to decrease adherence via as yet uncharacterized effects on
focal adhesions. This prepares the cell's response to subsequent directional cues. In summary, we conclude that ILK is involved in the
dynamic signaling events by which chemokines control leukocyte integrin
avidity for endothelial substrates.
We thank Kay Case of the Vascular Research
Division at the Brigham and Women's Hospital for preparation of human
endothelial cell cultures. We also thank Dr. Andrew Luster for
thoughtful review of the manuscript.
*
This work was supported by National Institutes of Health
Grants HL65584 and HL67768 (to R. E. G.); HL54202, AI40970, and
HL59521 (to A. R.); and HL61688 (to T. F.).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.
§
A Feodor-Lynen Research Fellow of the Alexander von Humboldt Foundation.
§§
To whom correspondence should be addressed: Center for Immunology
and Inflammatory Diseases, Massachusetts General Hospital East-8307,
149 13th St., Charlestown, MA 02129. Tel.: 617-724-8322; Fax:
617-726-5651; E-mail: gerszten@cvrc.mgh.harvard.edu.
Published, JBC Papers in Press, February 20, 2002, DOI 10.1074/jbc.M201240200
The abbreviations used are:
VCAM-1, vascular
cell adhesion molecule-1;
s, soluble;
ILK, integrin-linked kinase;
MCP-1, monocyte chemoattractant protein-1;
PI3K, phosphoinositide
3-kinase;
GSK-3, glycogen synthase kinase-3;
HUVEC, human umbilical
vein endothelial cell;
MOI, multiplicity of infection;
WT, wild-type;
KD, kinase-deficient;
EGFP, enhanced green fluorescent protein.
Role of Integrin-linked Kinase in Leukocyte Recruitment*
§,,
,
, and¶§§
Center for Immunology and Inflammatory
Diseases, ¶ Program in Cardiovascular Gene Therapy, Cardiovascular
Research Center, Massachusetts General Hospital, Charlestown,
Massachusetts 02129 and Harvard Medical School, Boston,
Massachusetts, Department of Biochemistry and Molecular
Biology, University of British Columbia and Jack Bell Cancer Centre
at Vancouver General Hospital and Health Service Center, Vancouver,
British Columbia V6H 3Z6, Canada and ** Molecular Cardiology
Research Institute, New England Medical Center, Tufts University
School of Medicine, Boston, Massachusetts 02111
ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1 integrins, is highly expressed in human
mononuclear cells and is activated by exposure of leukocytes to the
chemokine monocyte chemoattractant protein-1. Biochemical inhibitor
studies show that chemokine-triggered activation of ILK is downstream
of phosphoinositide 3-kinase. In functional assays under
physiologically relevant flow conditions, overexpression of wild-type
ILK in human monocytic cells diminishes 1
integrin/vascular cell adhesion molecule-1-dependent firm
adhesion to human endothelial cells. These data implicate ILK in the
dynamic signaling events involved in the regulation of leukocyte
integrin avidity for endothelial substrates.
INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
and
monocyte chemoattractant protein-1 (MCP-1) induce rapid activation of
leukocyte integrins such as 41, also
known as VLA-4. Subsequently, there is rapid deactivation and release
of the same integrin heterodimer from its counterligand, VCAM-1 (2). In
contrast to chemokines, nonphysiological leukocyte agonists such as
phorbol 12-myristate 13-acetate lock integrins into prolonged high
affinity states (2). The signaling pathways via which chemokines
dynamically modulate integrin affinity for endothelial and matrix
ligands to coordinate leukocyte adhesion and release are poorly understood.
1
integrins using a yeast two-hybrid screen with the 1
integrin cytoplasmic domain as bait (3). ILK expression has been
documented in the heart, skeletal muscle, kidney, and pancreas (3).
Sequencing of ILK revealed a 59-kDa protein serine-threonine kinase
with four ankyrin repeats in its N terminus. The C terminus is the integrin-interacting domain and also contains the kinase catalytic domain. Interposed between the ankyrin repeats and the kinase domain is
a pleckstrin homology domain thought to be important for the binding of
lipid second messengers such as those generated by PI3K (4). In
vitro, ILK can phosphorylate synthetic peptides corresponding to
1 integrin cytoplasmic domains (3). Other potential
substrates include the kinases Akt and glycogen synthase kinase
3 (GSK-3) (5). From a functional perspective, ILK overexpression in
epithelial cells disrupts cell-extracellular matrix as well as
cell-cell interactions. Recent data from studies in fibroblasts suggest
a potential role for ILK in cell motility via its interaction with the
focal adhesion protein PINCH (6). However, physiologically relevant cellular ligands that modulate ILK activity remain poorly understood (7, 8). Furthermore, a role for ILK in the dynamic processes
involved in leukocyte recruitment has not previously been postulated.
integrins and is
activated in a PI3K-dependent manner in other systems, we studied its role in leukocyte adhesion. Here we show that ILK is highly
expressed in human mononuclear leukocyte subsets and is activated by
exposure of leukocytes to chemokines. Chemokine-triggered activation is
sustained for several minutes and is dependent on PI3K. Interestingly,
overexpression of ILK in human monocytic cells diminishes
1 integrin/VCAM-1-dependent firm adhesion to human vascular endothelial cells. These data implicate ILK in the
dynamic signaling events involved in the regulation of leukocyte integrin avidity for endothelial substrates.
EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
(Ser9) (Cell Signaling), and
Akt/phospho-Akt-Ser473 (New England Biolabs). The epitope tag
was anti-V5 (Invitrogen). Leukocyte epitopes were CD11b and CD49D
(phycoerythrin-labeled; PharMingen). Adhesion molecules were 7A9
and H4/18 (to human E-selectin) (13), Hu5/3 (to human ICAM-1) (14),
E1/6 (which recognizes both human and rabbit VCAM-1) (15), Rb 1/9
(which recognizes only rabbit VCAM-1) (16), and IgG1 and
IgG2A control monoclonal antibody (PharMingen).
-glycerolphosphate, 2 mM dithiothreitol,
0.1 mM sodium orthovanadate, and 10 mM
MgCl2. Washed pellets were incubated with kinase buffer
supplemented with 200 µM ATP and 1 µg of the
commercially available GSK-3 substrate peptide (Cell Signaling) for 30 min at 30 °C. The kinase reaction was terminated by the addition of
SDS sample buffer, and the supernatants were boiled for 5 min at
100 °C and resolved by SDS-PAGE (10-12% gels). Membranes were
probed with phospho-GSK-3 (Ser9) antibody overnight at 4 °C
according to the manufacturer's instructions (Cell Signaling).
RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (33K):
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Fig. 1.
ILK expression in leukocyte subsets.
Lysates from human leukocyte subsets, purified as described under
"Experimental Procedures," were resolved by SDS-PAGE and Western
blotting performed with anti-ILK antibody.
integrins in other cell types, we investigated the effects of
chemokines on ILK activity in human leukocytes. We employed the
monocytic THP-1 cell line that mimics much of the phenotype of human
monocytes and is readily manipulated by somatic gene transfer
techniques for signaling studies (11). As seen in Fig.
2a, the chemokine MCP-1
activated ILK at physiologically relevant concentrations. 10-100-fold
higher doses of interleukin 8 also activated ILK, confirming that other chemokines can also activate ILK. Chemokine activation of ILK consistently peaked at ~30 s, lessened, and then increased and became
sustained for ~3 min (Fig. 2b). Importantly, we saw marked chemokine-triggered ILK activation in freshly isolated human monocytes as well (Fig. 2c). Because cell-matrix interactions have
been shown to activate ILK in other systems (3), we next assessed ILK
activation in THP-1 cells bound to VCAM-1, an important counterligand of 1 integrins in leukocyte recruitment. VCAM-1 binding
transiently activated ILK in our model (Fig. 2d), although
to a far lesser degree than chemokine stimulation. As a readout of ILK
activity for these studies, we employed an in vitro kinase
assay using a GSK-3 fusion protein substrate because GSK-3 has been
shown to be a target of ILK activation in other systems (5, 18). To
verify the specificity of the observed ILK activation by chemokines, we
assessed lysates immunoprecipitated with the ILK antibody for potentially contaminating kinases such as Akt (19). Akt is present in
whole cell lysates from THP-1 cells; importantly, however, Western blot analysis of the ILK immunoprecipitates revealed no Akt. In
addition, pretreating ILK precipitates with anti-Akt antibody before
the kinase assay had no effect on ILK phosphorylation of the GSK-3
fusion protein (data not shown).
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Fig. 2.
MCP-1 activates ILK in human monocytic
cells. a, human monocytic THP-1 cells were left
untreated or stimulated with the indicated concentration of MCP-1 or
interleukin 8 for 30 s (37 °C). Cell lysates were immunoprecipitated
with anti-ILK antibody, and kinase assays were subsequently performed
using a GSK-3 substrate peptide. After termination of the kinase
reaction, samples were resolved by SDS-PAGE, and membranes were probed
with an anti-phospho-GSK-3 (Ser9) antibody. b, THP-1
cells were stimulated with MCP-1 (100 nM, 37 °C) for the
indicated time period. c, freshly purified human
monocytes were stimulated with MCP-1 (100 nM, 30 s,
37 °C). d, THP-1 cells were incubated with
recombinant sVCAM-1 (25 µg/ml, 37 °C) for the indicated time
period. Where indicated, THP-1 cells were stimulated with MCP-1 (100 nM, 30 s, 37 °C). Representative data from one of
at least three experiments for each condition are shown.
(p85/p110, IA) isoform as well as PI3K-
(p101/p110, IB), which is thought to be activated exclusively by G
protein-coupled receptors (11, 20-22). A membrane-targeted, constitutively active PI3K construct stimulates ILK activity in NIH 3T3
cells (5). We next tested whether chemokines such as MCP-1 activate ILK
in a PI3K-dependent manner. As seen in Fig. 3, MCP-1 activated ILK, and pretreatment
of monocytes with low-dose wortmannin or LY294002 markedly attenuated
this activity. Pertussis toxin also abrogated ILK activation,
consistent with Gi-coupled chemokine receptor
signaling.
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Fig. 3.
Inhibitor studies. THP-1 cells were left
untreated or incubated with the inhibitors wortmannin, LY294002, or
pertussis toxin (60 min, 37 °C) at the indicated concentration.
THP-1 cells were then stimulated with MCP-1 (100 nM,
30 s, 37 °C) where indicated.
1
Integrin-dependent Adhesion--
Because biochemical
characterization suggested ILK activation by chemokines, we used
somatic gene transfer to probe potential downstream targets and assess
the functional effects on leukocyte recruitment. We manipulated THP-1
cell signaling using adenoviral constructs carrying the cDNAs for
wild-type and kinase-deficient ILK, first confirming expression by
Western blotting (Fig. 4A). Protein analysis revealed both endogenous 59-kDA ILK and the slightly larger epitope-tagged ILK protein. We next assessed the in
vitro ILK kinase activity of monocytic THP-1 cells transduced with
these constructs. We also assessed phosphorylation of Akt and GSK-3 in
whole cell lysates in chemokine-activated and ILK-transduced THP-1
cells. As noted previously, ILK can phosphorylate Akt and GSK-3 in
other systems (5, 19). Furthermore, Akt (23) and GSK-3 (24) are
downstream substrates of PI3K activation triggered by chemokines. As
seen in Fig. 4B, basal activity of uninfected THP-1
cells was low and was unaffected by control adenoviral infection. As
compared with AdEGFP- and AdKDILK-transduced THP-1 cells, we saw
increased ILK activity in the AdWTILK-transduced THP-1 cells, to levels
comparable to that seen with MCP-1 stimulation. In whole THP-1 cell
lysates, MCP-1 led to phosphorylation of both Akt and GSK-3, as did
AdWTILK transduction.
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Fig. 4.
Analysis of ILK-transduced THP-1 cells.
A, 2 × 106 THP-1 cells were
transduced with AdEGFP, AdWTILK, or AdKDILK (MOI = 10-50, as
indicated) or left uninfected ( 
). After 24 h in culture, cells
were lysed with lysis buffer and resolved by SDS-PAGE. Bottom
arrow indicates the endogenous 59-kDa ILK protein. Top
arrow indicates a slightly larger, exogenous, tagged construct.
B, 2 × 106 THP-1 cells were
transduced with AdEGFP, AdWTILK, or AdKDILK or left uninfected ().
Where indicated, cells were stimulated with MCP-1 (100 nM,
30 s, 37 °C). In the top panel, lysates were
immunoprecipitated with anti-ILK antibody. ILK activity was measured
using the GSK-3 substrate as described above. In the bottom
panels, whole THP-1 cell lysates were prepared before
immunoprecipitation, and Western blotting was performed with the
indicated antibody. Representative data from one of three experiments
are shown.
1 or 2 integrins that are critical for monocyte-endothelial interactions (Fig.
5). Having confirmed that the WT ILK
construct conferred increased activity at an MOI of 50 as measured by
in vitro kinase assays, we then investigated the functional
consequences of this activity in monocytic cells in our vascular flow
model. As seen in Fig. 6, uninfected and
AdEGFP-transduced THP-1 cells show moderate baseline adhesion to HUVEC
monolayers co-expressing E-selectin and VCAM-1. In this model,
E-selectin enhances initial leukocyte-endothelial tethering, whereas
firm adhesion is entirely blocked by monoclonal antibody blockade of
41 integrins interacting with their
VCAM-1 counterligand. Firm adhesion of both uninfected and
AdEGFP-transduced THP-1 cells was similarly enhanced by MCP-1 (100 nM). We saw a significant decrease in
VCAM-1-dependent firm adhesion of the WT ILK-transduced THP-1 cells, whereas adhesion of KD ILK-expressing cells was comparable to that of uninfected and control adenovirus-transduced cells. MCP-1
stimulation did not overcome the inhibition conferred by AdWTILK
transduction.
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Fig. 5.
Adenoviral gene transfer has no effect on
THP-1 1 and
2 integrins. THP-1 cells were
transduced with AdEGFP, AdILK, or AdKDILK (MOI = 10-50, as
indicated) or left uninfected (). 24 h after transduction, flow
cytometry experiments were performed using fluorescence-labeled
(non-fluorescein isothiocyanate) monoclonal antibody to CD49d
(1 integrin) and CD11B (2
integrin).
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Fig. 6.
ILK overexpression inhibits
VCAM-1-dependent adhesion. HUVECs were transduced with
AdE-sel and AdVCAM-1 (MOI = 50 for each) and cultured for 48 h. THP-1 cells were left untransduced or infected with AdEGFP, AdWTILK,
or AdKDILK in parallel with the biochemical analysis described above.
Leukocyte-endothelial interactions were studied at 2.0 dynes/cm2. Interactions were quantified 1 min before and 1 min after the addition of MCP-1 (100 nM). For antibody
blocking experiments, THP-1 cells were pretreated with
anti- 41 monoclonal antibody (10 µg/ml,
10 min, 4 °C). Uninfected, AdEGFP-transduced, and AdKDILK-transduced
THP-1 cell adhesion is comparably enhanced by MCP-1 (n = 4; *, p < 0.01 compared with baseline;
p = nonsignificant compared with each other.) Adhesion
of AdWTILK-transduced THP-1 cells, with and without chemokine, is
decreased significantly (n = 4; **,
p < 0.01) as compared with uninfected,
AdEGFP-transduced, and AdKDILK-transduced THP-1 cells. Cumulative data
from three experiments are shown.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1 integrins. ILK is emerging as an important transducer of cell-matrix signaling in a number of
physiological contexts. A role for ILK in the dynamic processes involved in leukocyte recruitment, however, has not previously been
postulated. Our data show that ILK is highly expressed in human
mononuclear subsets. Chemokines markedly activate ILK in both human
monocytes and the THP-1 cell line, which faithfully recapitulates
monocyte biology. Leukocyte engagement of the endothelial adhesion
molecule VCAM-1 also activates ILK. MCP-1-triggered activation of ILK
is dependent on PI3K in monocytes. Both MCP-1-activated THP-1 cells and
AdILK-transduced THP-1 cells share Akt and GSK-3 as downstream
substrates. Finally, a WT ILK construct diminishes baseline
VCAM-1-dependent adhesion and strikingly inhibits the MCP-1-triggered augmentation of monocyte arrest.
1 integrin-dependent adhesion of epithelial cells, it is not entirely surprising that it plays a similar role in
leukocyte adhesion in our system. Interaction between ILK and negative
modulators of integrin avidity in other systems, such as H-ras (30), is
presently unclear. 1 Integrin-associated proteins that
subserve similar functions in human neutrophils also merit
investigation. An unanswered question of obvious interest is how the
functional effects of other chemokines correlate with their effects on
ILK stimulation. Finally, future investigations must address the
relevant downstream targets of PI3K involved in leukocyte recruitment,
particularly in the context of ILK. Whereas our studies suggest that
phosphorylation of Akt and GSK-3 is seen by both chemokine-triggering
and transduction with ILK, they do not prove the functional relevance
of these observations. Precise definition of the contribution of
specific pathways will require additional investigation by engineering
new dominant negative constructs or perhaps in genetically manipulated
murine models.
ACKNOWLEDGEMENTS
FOOTNOTES
An Established Investigator of the American Heart Association.
ABBREVIATIONS
REFERENCES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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