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Previous Article | Next Article 
Molecular and Cellular Biology, January 2001, p. 438-448, Vol. 21, No. 2
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.2.438-448.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Lipopolysaccharide-Induced Activation of 
2-Integrin Function
in Macrophages Requires Irak Kinase Activity, p38
Mitogen- Activated Protein Kinase, and the Rap1 GTPase
Anja
Schmidt,1
Emmanuelle
Caron,1 and
Alan
Hall1,2,3,*
MRC Laboratory for Molecular Cell
Biology,1 CRC Oncogene and Signal
Transduction Group,2 and Department of
Biochemistry and Molecular Biology,3 University
College London, London WC1E 6BT, United Kingdom
Received 21 August 2000/Returned for modification 5 October
2000/Accepted 30 October 2000
 |
ABSTRACT |
Lipopolysaccharide (LPS), a component of the outer membrane of
gram-negative bacteria, is a potent activator of macrophages. Besides
inducing many transcriptional pathways, LPS also elicits rapid
morphological changes such as cell spreading. Here we have investigated
the signaling pathway that controls macrophage 
2-integrin-dependent spreading in response to LPS. We show that inhibition of the adapter protein MyD88, the interleukin-1 receptor-associated kinase Irak, the
p38 mitogen-activated protein kinase, or the Ras-like GTPase Rap1
blocks LPS-induced spreading. In addition, Irak activates p38 and
stimulates p38-dependent spreading. The activation of p38 by Irak
requires Irak's kinase activity. We find that p38 controls spreading
independently of its role in transcription but rather through
activation of Rap1. Together, our results suggest that
2-integrin-dependent spreading of macrophages in response to LPS is
controlled by a linear signaling pathway via MyD88, Irak, p38, and Rap1.
| |
INTRODUCTION |
Lipopolysaccharide (LPS), or
endotoxin, the major constituent of the plasma membrane of
gram-negative bacteria, is a strong activator of innate immune
responses and one of the main causative substances in the development
of septic shock (45, 52, 58). LPS is recognized by most
cell types, but its effects are mainly mediated by cells of the immune
and inflammatory system, including phagocytes and endothelial
cells. Several receptors for LPS that are expressed on the surface of
phagocytes have been described, including the
glycerophosphatidylinositol-linked protein CD14, 2-integrins, and the macrophage scavenger receptor
(14). The scavenger receptor does not seem to
function as a signaling receptor for LPS, and although
2-integrins may participate in signaling, there is strong
evidence that CD14 is the main mediator of LPS effects (15,
23-25, 27, 28).
In phagocytes, LPS induces many functional as well as morphological
alterations. These include the stimulation of transcription via
NF-
B, the Jnk and p38 mitogen-activated protein (MAP) kinase cascades, stimulation of nitric oxide (NO) production, activation of
phagocytosis via the complement receptor (
M2, CR3), and
stimulation of cell adhesion and spreading (13, 44, 56).
The best-understood signaling pathway induced by LPS is the
activation of transcription via NF-B and MAP kinases. LPS signaling
is initiated by the binding of LPS to the plasma protein LBP
(LPS-binding protein) which delivers LPS to CD14 (58).
CD14 lacks a cytoplasmic domain, and it has recently been suggested
that LPS signals are transduced through members of the Toll receptor
family (10, 26, 32, 42, 49, 50, 62). Toll was first
identified in Drosophila, where it is a key player in the
response to fungal infection in adult flies (37). In
mammals, several Toll-like receptors have been identified and there is
accumulating evidence that TLR4 (hToll) mediates LPS-induced signaling
(10, 26, 34, 42, 49, 50). Toll proteins possess a
cytoplasmic domain similar to the interleukin-1 (IL-1) receptor and
control NF-B and MAP kinase activation via a pathway that overlaps
in part with that used by the IL-1 receptor (34, 48). This
pathway includes the death domain, containing adapter protein MyD88 and
the IL-1 receptor-associated Ser/Thr kinase (Irak) (4, 29, 31,
43, 46, 55, 61). In IL-1 signaling MyD88 recruits Irak to the
receptor complex in a signal-dependent way (61). Upon
recruitment Irak is phosphorylated and then leaves the receptor complex
to interact with Traf6 (5). Traf6 is the only downstream
target of Irak identified so far, and it mediates IL-1-induced
activation of NF-B, Jnk, and p38 (3, 5). In LPS-Toll
signaling, Traf6 is also required for NF-B induction; however, it
does not seem to mediate Jnk activation (43, 46, 63).
Whether Traf6 is involved in LPS-Toll-induced p38 activation is not
known. Interestingly, several reports have suggested that the kinase
activity of Irak is not necessary for activating NF-B and Jnk
(33, 38, 41, 60).
One of the earliest cellular responses to LPS in macrophages is cell
spreading, but the signaling pathways involved are poorly defined
(22). The 2-integrin family, comprising L2,
M2, X2, and D2, plays a pivotal role in mediating
adhesion and spreading of leukocytes in response to a variety of
stimuli, including bacterial products, cytokines, and chemokines
(17). These stimuli activate 2-integrins through a
process called "inside-out" signaling, which might involve integrin
clustering, increases in integrin affinity, changes in the number of
integrins expressed at the cell surface, or cytoskeletal reorganization.
In this study, we investigated the molecular mechanisms by which LPS
induces 2-integrin-dependent spreading of the mouse macrophage cell
line J774.A1. We find that spreading is controlled by a linear
signaling pathway via MyD88, Irak, p38, and the Rap1 GTPase. The
activation of p38 requires Irak's kinase activity.
| |
MATERIALS AND METHODS |
Reagents and antibodies.
LPS from Escherichia
coli strain 055:B5 was obtained from Sigma. SB202190 was from
Calbiochem. TcdB-1470 was a gift from C. von Eichel-Streiber (Johannes
Gutenberg-University Mainz, Mainz, Germany). Polyclonal antibodies to
p38 and to dually phosphorylated p38 (Thr180, Tyr182) were purchased
from Santa Cruz and New England Biolabs, respectively. The anti-myc-tag
antibody (9E10) was a gift from S. Moss (University College London).
Monoclonal antibodies to mouse 4, mouse 2, mouse M, mouse
5, mouse 3, and mouse v integrins were from Pharmingen,
and antibodies to mouse 51 and human v5
(cross-reacting with mouse v5) were purchased from Chemicon.
Anti-Rap1 antibody was from Transduction Laboratories, anti-AU1
antibody was from Babco, and anti-HA antibody was from Boehringer
Mannheim. Fluorescently and horseradish-peroxidase (HRP)-conjugated
secondary antibodies were from Jackson ImmunoResearch and Pierce.
AMCA-streptavidin and biotin-, fluorescein isothiocyanate (FITC)-, and
Texas red-dextran were from Molecular Probes. Rhodamine-phalloidin was
purchased from Sigma.
cDNA constructs.
The pRK5myc expression vector has been
previously described (35). pRK5myc::Irak (pAS310) encoding
human Irak was constructed by PCR using pcDNA3::Irak as the template
(V. Goeddel, Tularik, San Francisco, Calif.). pRK5myc::IrakN
(pAS311) is a deletion variant of pAS310, encoding the N-terminal 239 amino acids of human Irak, and was made by PCR with pcDNA3::Irak
as the template.
pRK5myc::IrakD358N (pAS323) encodes the Irak kinase-dead protein in
which aspartate 358 is replaced by an asparagine residue. pAS323 was
reconstituted from two PCR fragments generated with primers
5'-GACACCCAAGCTTGGAAACTTTGGCCTGGCCCGGTTCAGC-3' and 5'-AGTCTCCAAGCTTGGGTGTCAGCCTCTCATCCAG-3',
each in combination with a flanking primer and with pAS310 as the
template. A silent nucleotide substitution that created a
HindIII site is indicated in bold, and the point
mutations that created the kinase-dead mutation are underlined.
pRK5myc::MKK6* (pAS328), which encodes a constitutively active human
MKK6 protein with serine 207 and threonine 211 replaced by glutamate
residues, was made by PCR with pcDNA3::Flag-MKK6(Glu) as the template
(R. Davis, University of Massachusetts Medical School). PCRs were done
using Taq polymerase (Boehringer Mannheim). Constructs were
verified by sequencing.
pRK5myc::N17Rap1 containing a dominant-negative allele of Rap1,
pGEX-2T::RalGDS-RBD expressing the Rap1-binding domain of Ral GDS fused
to Gst, and pRK5myc::N43R-Ras encoding dominant-negative R-Ras were
provided by A. Self (University College London). pMT2-HA-RalA (N28)
encoding N28RalA was provided by Johannes Bos (University of Utrecht).
pcDL-SR-HA::p38AGF contains dominant-negative p38 and was
provided by E. Nishida (Kyoto University). pcDNA3::HA-p38 contains
the human p38 gene (H. Nishitoh, Cancer Institute, Tokyo, Japan).
pcDNA3::AU1-MyD88
encodes dominant-negative MyD88, which lacks amino
acids 1 to 152, and was provided by M. Muzio (Mario Negri Institute,
Milan, Italy).
J774.A1 cell culture and microinjection.
J774.A1 macrophages
were grown in Dulbecco's modified Eagle's medium (DMEM) supplemented
with 10% heat-inactivated fetal calf serum (HIFCS) (Sigma) and 1%
penicillin and streptomycin (PEN-STR) at 37°C. Cells for
microinjection were plated overnight onto acid-washed glass coverslips
(13 mm) in four-well plates at a density of 105 cells/ml
per well. FITC- or Texas red-dextran or eukaryotic expression vectors
(0.1 µg/µl, unless stated otherwise), together with biotin-dextran, were injected into the nucleus of 50 to 100 cells over a period of 15 min. Cells were returned to the incubator for 2 to 5 h for optimal expression.
J774.A1 spreading assay.
To assay spreading of macrophages
in response to LPS, cells were plated overnight onto acid-washed glass
coverslips (13 mm) in DMEM, 10% HIFCS, and 1% PEN-STR in four-well
plates at a density of 105 cells/ml per well. Cells were
then incubated with LPS (1 µg/ml) for 10 min unless stated otherwise,
fixed, and stained with rhodamine-phalloidin (see below). Drugs or
blocking antibodies were added prior to LPS addition at the indicated
concentrations and for the indicated length of time. On average, 200 cells were counted per coverslip and the percentage of spread cells was calculated.
To assay spreading of macrophages expressing cDNAs, cells were
microinjected as described above, then treated or not treated with
inhibitors or LPS at the indicated concentrations and for the indicated
length of time, fixed, and stained for expression of proteins using
anti-myc, anti-HA, or anti-AU1 antibodies before staining with
rhodamine-phalloidin (see below). Spreading was assessed in the
retrieved cells expressing cDNAs.
All experiments were repeated at least three times and the data are
presented as the means ± standard deviations. Representative pictures of cells are shown below.
Immunofluorescence staining protocols.
Microinjected and
LPS- and/or drug-treated J774.A1 cells on coverslips were fixed with
4% paraformaldehyde-phosphate-buffered saline (PBS) for 10 min,
permeabilized in 0.2% Triton X-100-PBS for 5 min, incubated with
NH4Cl in PBS (2.7 mg/ml) for 10 min to remove free aldehyde
groups, and then stained as previously described (47).
Coverslips were rinsed in PBS between each step of the staining
procedure. Primary antibodies were diluted in PBS, 0.5% bovine serum
albumin, and 1 µg of human immunoglobulin G (IgG)/ml and left on the
coverslip for 45 min. After washing, the coverslips were incubated for
45 min with fluorescently conjugated secondary antibodies and
AMCA-coupled streptavidine (to retrieve biotin-dextran-injected cells)
diluted in PBS, 0.5% bovine serum albumin, and 1 µg of human IgG/ml.
For spreading assays, cells were further incubated with
rhodamine-phalloidin (200 ng/ml) for 5 min. Coverslips were mounted on
moviol mountant containing p-phenylenediamine as an
antibleaching agent. After 1 h at room temperature, the coverslips
were examined and the cells were counted on a Zeiss axiophot microscope
using Zeiss 63×1.4 oil-immersion objectives. Pictures were taken with
a Hamamatsu C5985-10 video camera.
Transfection of COS-1 cells.
COS-1 cells were grown in DMEM
containing 10% FCS and 1% PEN-STR. Cells were seeded in six-well
plates at a density of 2 × 105 cells per well in 2 ml
of medium, incubated overnight, and transfected using Lipofectamine
(Gibco-BRL), according to the manufacturer's instructions. A total of
1 µg of DNA was used for each transfection. After transfection the
cells were incubated at 37°C for 24 h. The medium was replaced
with 2 ml of DMEM-10% FCS-1% PEN-STR, and the cells were incubated
overnight at 37°C and then harvested.
Preparation of cell extracts for phospho-p38 analysis, SDS-PAGE,
and Western analysis.
Extracts from J774.A1 or transfected COS-1
cells were prepared as follows. J774.A1 cells were seeded in six-well
plates at a density of 2 × 105 cells per well in 2 ml
of DMEM-10% HIFCS-1% PEN-STR and incubated overnight at 37°C
before treatment with inhibitors and LPS. COS-1 cells were transfected
as described above. Cells were washed with ice-cold PBS and then
incubated with 250 µl of lysis buffer (20 mM Tris-HCl [pH 7.5], 150 mM NaCl, 1% Triton X-100, 12 mM -glycerophosphate, 5 mM EGTA, 0.5%
deoxycholate, 1 mM dithiothreitol, 10 mM NaF, 1 mM
Na3VO4, 0.1 mM phenylmethylsulfonyl fluoride
[PMSF], 20 µg of aprotinin/ml, 20 µg of leupeptin/ml) for 20 min
on ice. Cell debris was removed by centrifugation at 13,000 rpm for 10 min at 4°C. Samples were denatured at 95°C for 5 min. Sodium
dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and
Western analysis were performed by standard methods. Thirty micrograms of protein extract was loaded in each lane.
Purification of RalGDS-RBD.
pGEX-2T::RalGDS-RBD was
transformed into E. coli strain BL21. Protein production was
initiated by adding IPTG to the culture. The bacteria were lysed by
sonication and fusion protein was affinity purified on
glutathione-beads by standard methods.
Rap1 activation assay using RalGDS-RBD.
Rap1 pull-down
assays were performed as described (16). J774.A1 cells
were seeded in 15-cm-diameter dishes at a density of 2.5 × 106 cells per dish in 20 ml of DMEM-10% HIFCS-1%
PEN-STR and grown for 64 h at 37°C before treatment with
inhibitors and LPS. Cells were washed twice in cold TBS buffer (10 mM
Tris-HCl [pH 7.5], 150 mM NaCl) and lysed in lysis buffer (50 mM
Tris-HCl [pH 7.5], 500 mM NaCl, 10 mM MgCl2, 1% NP-40,
10% glycerol, 1 mM PMSF, 20 µg of aprotinin/ml, 20 µg of
leupeptin/ml). Cell debris was removed by centrifugation at 15,000 × g for 2 min at 4°C. Twenty micrograms of Gst-RalGDS-RBD
coupled to glutathione beads was added to each supernatant, and the
mixture was incubated at 4°C for 45 min on a rotating wheel. Beads
were washed three times with lysis buffer containing 200 mM NaCl.
Samples were denatured for 5 min at 95°C and subjected to SDS-PAGE
and Western analysis using the anti-Rap1 antibody.
| |
RESULTS |
LPS induces spreading of J774.A1 macrophages.
To investigate
the effect of LPS on the morphology of the mouse macrophage cell line
J774.A1, cells were grown on glass coverslips in the presence of 10%
serum and then treated or not treated with LPS (1 µg/ml). Within 10 min of LPS addition, between 60 and 70% of the macrophages had changed
their morphology from round to flat and spread, as seen by
visualization of the actin cytoskeleton (Fig.
1 and 2A).
Less than 15% of the non-LPS-treated cells exhibited the spreading
form. Thus, LPS induces spreading of J774.A1 macrophages.
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FIG. 1.
Antibodies against 2- and M-integrins block
LPS-induced spreading of J774.A1 macrophages. Macrophages were treated
or not treated with blocking antibodies against 4, 51, 2,
M, 3, v, or v5 integrins at a final concentration of 15 µg/ml in the presence of 50 µg of human IgGs for 30 min at 37°C
and then were incubated with or without LPS (1 µg/ml) for 10 min.
Cells were fixed and stained with rhodamine-phalloidin and the
percentage of spreading cells was determined.
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FIG. 2.
Rap1 is required for LPS-induced spreading of J774.A1
macrophages. (A and B) TcdB-1470 inhibits LPS-induced spreading of
macrophages. Macrophages were treated with or without TcdB-1470 (10 pg/ml) for 2 h at 37°C and then incubated with or without LPS (1 µg/ml) for 10 min. Cells were fixed and stained with
rhodamine-phalloidin and the percentage of spread cells was determined.
(C) Expression of dominant-negative Rap1 prevents LPS-induced
spreading. Macrophages were microinjected with FITC-dextran or with
cDNA constructs encoding myc-tagged N17Rap1 (0.25 µg/µl),
myc-tagged N43R-Ras, or HA-tagged N28RalA, returned to the incubator
for expression of the constructs, and then treated with or without LPS
(1 µg/ml) for 10 min. Cells were fixed, stained with anti-myc and
anti-HA antibody, respectively, and rhodamine-phalloidin, and the
percentage of injected or expressing spreading cells was determined.
The background of spread cells is usually around 10% higher when cells
were microinjected (compare  LPS controls in panels B and C).
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LPS-induced spreading is mediated by 2-integrins.
Because
LPS-induced spreading is studied using macrophages that are seeded on
glass coverslips in the presence of serum, the nature of the
cell-matrix interaction is not known. To assess whether LPS-induced
spreading is mediated by integrins, EDTA, a divalent cation chelator
that is known to block integrin function, was added to macrophages
prior to LPS treatment. Pretreatment with EDTA completely inhibited
LPS-induced spreading (data not shown). Next, we tested blocking
antibodies, directed against various integrin - and -subunits,
for their ability to inhibit LPS-induced spreading. Preincubation with
an antibody against the 2-chain almost completely inhibited
spreading induced by LPS (Fig. 1). The anti-M antibody partially
blocked LPS-induced spreading, whereas antibodies against 4,
51, 3, v, or v5 had no effect. This suggests that
LPS-induced spreading is mediated by 2-integrins, possibly by the
M2-integrin. A role for 2-integrins other than M2 cannot
be excluded but could not be tested, as suitable blocking antibodies
against these -chains were not available.
The Rap1 GTPase is required for LPS-induced spreading.
Caron et al. have recently shown that the small Ras-like GTPase
Rap1 activates M2 (CR3)-mediated phagocytosis. Furthermore, Rap1
is activated by LPS, and is required for LPS-induced M2 (CR3)-mediated phagocytosis (6). These results have
indicated that Rap1 activates the M2-integrin. We therefore
investigated whether Rap1 is involved in LPS-induced spreading which is
also mediated by 2-integrins. For this purpose we made use of
TcdB-1470, a cytotoxin from Clostridium difficile which
inhibits Ras-like GTPases including Rap1, R-Ras, and RalA, as well
as the Rho-GTPase Rac (9). As seen in Fig. 2A and B,
pretreatment with TcdB-1470 (10 pg/ml) fully inhibited LPS-induced spreading.
To determine which GTPase is involved in LPS-induced spreading,
cDNAs encoding dominant-negative versions of Rap1, R-Ras, RalA, and Rac
were injected into macrophages prior to LPS treatment. Cells expressing
N17Rap1 did not spread in response to LPS, whereas injection of control
DNA, N43R-Ras, N28RalA, or N17Rac did not impair LPS-induced spreading
(Fig. 2C and data not shown). This indicates that Rap1 controls
2-mediated spreading in response to LPS.
LPS-induced spreading is dependent on the p38 MAP kinase.
p38
plays an important role in mediating LPS-induced transcription and
cytokine production (2, 7, 8, 11, 20, 36, 40), and it also
has been implicated in the activation of LPS-induced
2-integrin-dependent adhesion of polymorphonuclear leukocytes to
fibrinogen (12). We therefore asked whether activation of
p38 is required for LPS-induced spreading of macrophages. J774.A1 cells
were pretreated with the p38-specific inhibitor SB202190 and then
stimulated with LPS. Pretreatment with SB202190 (0.1 to 10 µM)
inhibited macrophage spreading induced by LPS in a dose-dependent way
(Fig. 3A and B). A 50% inhibition of
spreading was observed at concentrations between 0.1 and 0.5 µM,
which is in agreement with the published 50% inhibitory concentration
(IC50) of ~0.3 µM for SB202190. To confirm the
involvement of p38 in LPS-induced spreading, a cDNA construct encoding
dominant-negative p38 was microinjected into macrophages prior to LPS
treatment. Expression of dominant-negative p38 severely decreased the
number of spread cells (Fig. 3C). Together these results suggest that
p38 is required for LPS-induced spreading.
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FIG. 3.
p38 MAP kinase is required for LPS-induced spreading of
J774.A1 macrophages. (A and B) SB202190 blocks LPS-induced spreading of
macrophages. Macrophages were treated with or without SB202190 (A, 1 µM; B, 0.1 to 10 µM) for 20 min at 37°C, incubated with or
without LPS (1 µg/ml) for 10 min, fixed, stained with
rhodamine-phalloidin, and then assayed for spreading. (C) Expression of
dominant-negative p38 inhibits LPS-induced spreading. Macrophages were
microinjected with FITC-dextran () or a cDNA construct encoding for
HA-tagged dnp38, returned to the incubator for expression of the
construct, and then treated with or without LPS (1 µg/ml) for 10 min.
Cells were fixed and stained with anti-HA antibody and
rhodamine-phalloidin, and the percentage of injected/expressing spread
cells was determined. (D) The time course of LPS-induced spreading
correlates with the time course of p38 activation. (Top and middle
panels) Macrophages were incubated with LPS (1 µg/ml) for the
indicated times and then lysed. Whole cell extracts were prepared and
subjected to SDS-PAGE and Western analysis using anti-p38 (middle) and
anti-phospho-p38 (top) antibodies. (Bottom panel) Macrophages were
incubated with LPS (1 µg/ml) for the indicated times, fixed, and
stained with rhodamine-phalloidin, and the percentage of spread cells
was determined.
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Next, we investigated whether the time course of p38 activation by LPS
correlated with the time course of spreading. Macrophages were treated
with LPS for various lengths of time and the percentage of spread cells
was assessed. Figure 3D shows that LPS stimulates spreading rapidly and
transiently. Spread macrophages were seen 5 min after LPS addition; the
percentage of spread cells was maximal after 10 min of treatment and
declined after 30 to 40 min. We then examined the kinetics of p38
phosphorylation following LPS treatment. Whole cell extracts from cells
treated with LPS for various lengths of time were prepared and
subjected to SDS-PAGE and Western analysis using an antibody that
specifically recognized phosphorylated, i.e., activated, p38 (Fig. 3D).
Like spreading, phosphorylated p38 could be detected after 5 min,
reached a maximum after 10 min, and declined after 30 to 40 min. The
time course for p38 activation was therefore consistent with its
participation in LPS-induced spreading.
The above results show that p38 activation and spreading occur within
minutes of LPS treatment and that there is no lag phase between the two
processes. It is thus unlikely that p38 controls spreading by
activating transcription; p38 might have a second function, outside the
nucleus and independent of transcription. We therefore wanted to know
where activated p38 was localized in LPS-treated cells, and so we
performed immunofluorescence on LPS-treated and nontreated cells using
the anti-phospho-p38 antibody. In agreement with the biochemical data
shown in Fig. 3C, very little activated p38 could be seen in
unstimulated cells (see Fig. 5A). In contrast, LPS-treated macrophages
contained high levels of activated p38. Interestingly, phosphorylated
p38 was found both inside as well as outside the nucleus in LPS-treated cells. Together these data suggest that the role of p38 in LPS-induced spreading is independent of its function in activating transcription.
Activation of p38 is sufficient to induce spreading of
macrophages.
We next wanted to know whether activation of p38 is
sufficient to activate spreading. The MAP kinase kinase MKK6
selectively phosphorylates and activates p38 (21). An
expression vector encoding a constitutively active, myc-tagged
MKK6 (MKK6*) was microinjected into J774.A1 macrophages. Cells
were fixed and stained for phosphorylated p38. MKK6*-expressing
cells showed high levels of phosphorylated p38 compared to
control-injected cells, confirming that MKK6 can activate p38 (data not
shown). Like LPS, MKK6* activated p38 both inside and outside the
nucleus (data not shown). We then assayed MKK6*-injected cells for
spreading. As can be seen in Fig. 4A and
B, approximately 55% of the cells
expressing MKK6* were spread compared to only 22% of the
control-injected cells. This suggests that activation of p38 is
sufficient to induce spreading of macrophages.
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FIG. 4.
Activated MKK6 induces Rap1-dependent spreading in
J774.A1 macrophages. (A and B) Macrophages were microinjected with FITC
dextran (), or a cDNA construct encoding for myc-tagged activated
MKK6 (MKK6*). Cells were returned to the incubator for expression of
the construct, and treated or not treated with TcdB-1470 (10 pg/ml) for
2 h at 37°C. Cells were fixed and stained with anti-myc antibody
and rhodamine-phalloidin and the percentage of expressing/injected
spread cells was counted.
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Rap1 functions downstream of p38.
We next asked whether Rap1
functions upstream or downstream of p38 in controlling macrophage
spreading. For this purpose, we analyzed if pretreatment with
TcdB-1470 prevents LPS-induced p38 activation as seen by
immunofluorescence. Although TcdB-1470 blocked spreading in
response to LPS, p38 was still activated (Fig.
5A). TcdB-1470
treatment alone did not activate p38. Also, we prepared protein
extracts from cells treated with TcdB-1470 and LPS and subjected them
to SDS-PAGE and Western analysis, probing for phosphorylated p38.
Consistent with the result obtained by using immunofluorescence,
TcdB-1470 did not inhibit LPS-induced p38 activation (Fig. 5B). This
suggests that Rap1 is not upstream of p38 in the LPS-spreading pathway.
Because p38 activation is sufficient to induce spreading, it is
likely that Rap1 is downstream of p38. To gain further evidence
for this, we investigated whether TcdB-1470 blocks MKK6*-induced
spreading. Following microinjection of MKK6* DNA, cells were treated
or not treated with TcdB-1470 and assayed for spreading. Figure 4B
shows that the number of MKK6*-expressing cells which were spread was
severely reduced upon treatment with TcdB-1470. Finally, we checked
whether activation of Rap1 by LPS was blocked by the p38 inhibitor
SB202190. Activation of Rap1 was measured by "pull-down"
experiments using the Rap1-binding domain of RalGDS as an
activation-specific probe. As described previously, LPS stimulated
activation of Rap1 (Fig. 5C and D) (6). However,
pretreatment of cells with the p38 inhibitor strongly decreased the
activation of Rap1 in response to LPS (Fig. 5C and D). Therefore, Rap1
functions downstream of p38 in the control of spreading.
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FIG. 5.
Rap1 is downstream of p38. (A and B) TcdB1470 does not
inhibit LPS-induced p38 activation in J774.A1 macrophages. Macrophages
were treated with or without TcdB-1470 (10 pg/ml) for 2 h at
37°C and then incubated with or without LPS (1 µg/ml) for 10 min.
Cells were fixed and stained with anti-phospho-p38 antibody (A), or
cells were lysed and whole cell extracts were subjected to SDS-PAGE and
Western analysis using the anti-phospho-p38 and anti-p38 antibodies
(B). (C and D) SB202190 inhibits LPS-induced Rap1 activation in
macrophages. Cells were incubated with or without SB202190 (5 µM) for
20 min at 37°C, incubated with or without LPS (0.1 µg/ml) for 15 min, and lysed. Extracts were incubated with 20 µg of
Gst-RalGDS-RBD precoupled to gluthathione beads to isolate GTP-bound
(activated) Rap1. Levels of activated Rap1 were monitored by Western
analysis with anti-Rap1 antibody (upper panel). Levels of Rap1 in total
lysates are shown in the lower panel. (D) Western blots of five
individual experiments were scanned and quantified. Rap1GTP
levels were normalized to total Rap1 levels, and the activation of Rap1
by LPS in the presence or absence of SB202190 was calculated as fold
activation of Rap1 compared to non-LPS-treated cells.
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|
LPS-induced spreading is mediated via MyD88 and Irak.
Irak and
MyD88 have been shown to mediate LPS/Toll-induced activation of NF-B
and MAP kinases (31, 43, 46, 55). We therefore wanted to
know whether Irak and MyD88 are also required for LPS-induced
spreading. For this purpose, Irak and MyD88 deletion constructs (Irak N
and MyD88, respectively) were made. Such constructs behave as
dominant-negative alleles, as shown by their ability to block
LPS/TLR4-induced NF-B activation (43, 46; also data not
shown). Irak N and MyD88 did not induce significant spreading when
microinjected into macrophages (Fig. 6A).
When microinjected prior to LPS addition, Irak N and MyD88
inhibited the induction of spreading by LPS (Fig. 6A). This suggests
that LPS-induced spreading of macrophages is mediated via MyD88
and Irak.
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|
FIG. 6.
(A) LPS-induced spreading requires Irak and MyD88;
Irak-induced spreading is dependent on p38 and Rap1. Shown here is the
induction of macrophage spreading by Irak and MyD88 constructs in the
presence or absence of LPS, SB202190, or TcdB-1470. Macrophages were
microinjected with FITC-dextran () or cDNAs encoding for myc-tagged
Irak wild-type and mutant constructs or AU1-tagged MyD88. Cells were
returned to the incubator for expression of the constructs and then
incubated as indicated either with LPS (1 µg/ml) for 10 min, SB202190
(1 µM) for 20 min, or TcdB-1470 (10 pg/ml) for 2 h. Cells were
then fixed, stained with anti-myc or anti-AU1 antibodies and
rhodamine-phalloidin, and assayed for spreading. (B) Irak induces
spreading in J774.A1 macrophages. Macrophages were microinjected with
FITC-dextran (control) or a cDNA construct encoding for myc-tagged
Irak. Cells were returned to the incubator for expression of the
construct, fixed and stained with anti-myc and rhodamine-phalloidin,
and assayed for spreading.
|
|
Irak induces p38- and Rap1-dependent spreading.
Next, we asked
whether overexpression of Irak was sufficient to induce spreading in
macrophages. For this purpose, Irak DNA was microinjected into
macrophages and cells were assayed for spreading. Figure 6A and B show
that more than 60% of cells expressing Irak were spread compared to
control-injected cells.
To determine whether Irak was upstream of p38 in mediating spreading,
we asked whether Irak could activate p38. Irak DNA was microinjected
into macrophages and immunofluorescence was performed using the
anti-phospho-p38 antibody. As seen in Fig. 7A and
B, unlike control-injected cells, cells
expressing Irak showed high levels of phosphorylated p38. Next, we
wanted to confirm this result biochemically. Because J774.A1
macrophages cannot be transfected, we transfected COS-1 cells with Irak
and control DNA. Cell extracts were prepared and subjected to SDS-PAGE
and Western analysis using the anti-phospho-p38 antibody. As shown in
Fig. 7C, expression of Irak in COS-1 cells, as in macrophages,
stimulated phosphorylation of p38. Next we investigated whether
Irak-induced spreading was dependent on p38. Macrophages were
microinjected with Irak DNA, treated or not treated with the
p38-inhibitor SB202190, and assayed for spreading. Irak-expressing
cells that had been treated with SB202190 did not spread (Fig. 6A).
These data suggest that Irak is upstream of p38 in mediating
LPS-induced spreading. We also tested whether Irak induced spreading
via the Rap1 GTPase. Macrophages were microinjected with Irak DNA
and treated with TcdB-1470 before the spreading assay. As expected,
pretreatment with TcdB-1470 prevented Irak-induced spreading,
confirming that Irak is also upstream of Rap1 (Fig. 6A).
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FIG. 7.
(A and B) Irak's kinase activity is required for
activation of p38 in J774.A1 macrophages. Macrophages were
microinjected with Texas red-dextran (control) or cDNAs encoding
myc-tagged Irak, Irak D358N, or Irak N. Cells were fixed and stained
with anti-myc (C, E, and G) or anti-phospho-p38 (B, D, F, and H)
antibodies. The percentage of cells with activated p38 was determined.
(C) Irak's kinase activity is required for activation of p38 in COS-1
cells. cDNAs encoding myc-tagged Irak, Irak D358N, or Irak N and
control DNA () together with cDNA encoding for p38 were
transfected into COS-1 cells. Whole cell extracts were prepared and
subjected to SDS-PAGE and Western analysis using anti-phospho-p38 (top
panel), anti-p38 (middle panel), and anti-myc (bottom panel)
antibodies. The band above Irak N, which is visible in all four lanes,
is due to cross-reactivity with the secondary antibody.
|
|
Irak's kinase activity is required for activation of p38.
Several reports have stated that Irak's kinase activity is not needed
for the activation of NF-B and Jnk MAP kinase (33, 38,
41). We therefore wanted to know whether Irak's kinase activity
was required for the induction of p38 and spreading. A kinase-dead
allele of Irak (Irak D358N) was constructed by introducing a point
mutation into the sequence encoding the phosphotransfer site of the
kinase motif, changing aspartate 358 to asparagine. Irak D358N was
injected into macrophages and cells were stained with the
anti-phospho-p38 antibody. In contrast to Irak-expressing cells, very
little phosphorylated p38 could be detected in cells expressing Irak
D358N (Fig. 7A and B). Phospho-p38 levels were similar to those in
cells expressing nonfunctional Irak N or in control-injected cells. To
confirm this result biochemically, Irak D358N was transfected into
COS-1 cells, extracts were prepared and subjected to SDS-PAGE and
Western analysis using the anti-phospho-p38 antibody. Figure 7C shows
that in contrast to Irak, Irak D358N did not activate p38 in COS-1
cells, although both proteins were expressed at a comparable level. In
addition, whereas the Irak wild-type protein appeared as two bands
which presumably correspond to unphosphorylated and autophosphorylated
Irak (4, 38, 41), no autophosphorylated form of Irak D358N
could be detected, suggesting that Irak D358N indeed is inactive.
Therefore, we conclude that Irak's kinase activity is required to
activate p38.
Next we examined whether Irak D358N induces spreading of macrophages.
Irak D358N was significantly less efficient than wild-type Irak in
inducing spreading (Fig. 8A). Since the
mutant Irak construct can still dimerize with endogenous, wild-type
Irak, it is possible that Irak D358N can induce low levels of p38
activation which might be undetectable in the immunofluorescence assay
but sufficient to allow induction of some spreading. To investigate
this, we transfected COS-1 cells with increasing amounts of Irak D358N DNA, prepared cell extracts, and subjected them to SDS-PAGE and Western
analysis probing for phosphorylated p38 (Fig. 8B). Indeed, when Irak
D358N was expressed at very high levels, some activated p38 could be
detected.
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FIG. 8.
(A) Some residual activity is associated with Irak D358N
which is sufficient to induce some spreading of macrophages.
Macrophages were microinjected with FITC-dextran (control) or cDNAs
encoding myc-tagged Irak, Irak D358N, or Irak N. Cells were then fixed,
stained with anti-myc antibody and rhodamine-phalloidin, and assayed
for spreading. (B) Overexpression of Irak D358N induces some p38
activation. COS-1 cells were transfected with cDNA encoding for p38
along with control DNA (), a cDNA construct encoding for myc-tagged
Irak, or with increasing amounts of cDNA encoding for myc-tagged Irak
D358N. Whole cell extracts were prepared and subjected to SDS-PAGE and
Western analysis using anti-phospho-p38 (top panel), anti-p38 (middle
panel), and anti-myc (bottom panel) antibodies.
|
|
| |
DISCUSSION |
Macrophages respond to LPS by changing their morphology from a
round to a spread form (44). Here, we describe several
findings concerning the signaling pathway by which LPS stimulates
macrophage spreading. First, LPS-induced spreading is inhibited by
antibodies against 2-integrins. Second, dominant-negative
versions of MyD88, Irak, p38 MAP kinase, or Rap1 block LPS-induced
spreading. Third, Irak activates p38 and stimulates p38-dependent
spreading. Fourth, the activation of p38 by Irak is dependent
on its kinase activity. Fifth, LPS-induced activation of Rap1
requires p38. Together these results suggest that
LPS-induced 2-integrin-dependent spreading is mediated by a linear
pathway via MyD88, Irak kinase, p38, and Rap1. A model summarizing our
data is shown in Fig. 9.
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FIG. 9.
Model of LPS-induced signaling pathways leading to
activation of transcription and spreading. LPS-induced spreading is
mediated by a linear pathway, comprising MyD88, Irak, p38, Rap1, and
2-integrins. See Discussion for further details.
|
|
The role of Irak's kinase activity in IL-1 and LPS signaling is
unclear at present. The majority of reports have stated that the kinase
activity of Irak is not required for the activation of NF-B and Jnk.
Overexpression of an Irak kinase-dead mutant, like overexpression of
Irak, leads to activation of NF-B and Jnk and also restores IL-1
signaling in Irak-deficient cells (33, 38, 41, 60). In
contrast, Vig et al. found that overexpression of a kinase-dead mutant
of mouse Irak did not activate a NF-B-dependent reporter gene
(59). Furthermore, pelle, the Drosophila
homolog of Irak, has been reported to require its kinase activity to
rescue pelle null mutants and for the activation of
dorsal, the fly NF-B homolog (18, 54). The
role of Irak's kinase activity in inducing p38 MAP kinase has not been
investigated. Here we find that an Irak kinase-dead mutant (Irak D358N)
is unable to activate p38 MAP kinase in macrophages and COS-1 cells
when expressed at levels similar to those of wild-type Irak. This
suggests that the kinase activity of Irak is required for the
activation of at least some downstream signaling pathways. Although
Irak D358N did not induce detectable activation of p38 in macrophages,
it still induced some spreading. It is likely that Irak D358N induces
some activation of p38 but that the immunofluorescence assay with the
phospho-p38 antibody is not sensitive enough to detect small increases.
When expressed in COS-1 cells at high levels, Irak D358N is able to induce some p38 activation, and it appears that some catalytic activity
is still associated with Irak D358N. This is probably due to its
ability to form heterodimers with endogenous wild-type Irak, as shown
previously, and such heterodimers might be partially active
(60).
What might be downstream of Irak in activating p38? So far the only
known downstream target of Irak is Traf6 (5). Traf6 mediates the activation of NF-B, Jnk, and p38 in response to IL-1
(3, 5) and also is required for the stimulation of NF-B
by LPS/Toll (43, 46, 63). However, in contrast to IL-1
signaling, Traf6 does not mediate the Toll-induced activation of Jnk
(46). Our preliminary results show that dominant-negative Traf6 does not block Irak-induced p38 activation in COS-1 cells and
reduces LPS-induced spreading of macrophages by only 30%. This
relatively small effect suggests that Traf6 is not involved in the
activation of p38/spreading by LPS in macrophages (A.S. and A.H.,
unpublished observations). Thus although the general concept of the
IL-1 and LPS/Toll signaling pathways appears to be conserved,
individual components of the pathways may differ. It will be
interesting to see whether other Irak targets can be identified which
mediate the activation of Jnk and p38 in response to LPS/Toll.
The role of p38 MAP kinase in the control of transcription has been
studied in detail; however, little is known about functions that p38
can have independently of protein synthesis. Our results suggest that
the MAP kinase p38 controls macrophage spreading in response to LPS and
that it does so independently of transcription/protein synthesis.
First, the p38-specific inhibitor SB202190 or dominant-negative p38
inhibits spreading in response to LPS. Second, activation of p38 by
constitutively active MKK6 induces spreading. Third, both p38
activation and spreading occur within minutes of LPS treatment and
there is no lag phase between p38 activation and spreading. Fourth,
phosphorylated, activated p38 can be found both inside and outside the
nucleus following stimulation of macrophages with LPS. In agreement
with our findings, Detmers et al. have also reported that p38 is
required for the LPS-induced activation of 2 integrin-dependent
adhesion of polymorphonuclear leukocytes to fibrinogen and the
subsequent oxidative burst and that this does not require protein
synthesis (12).
How might p38 control macrophage spreading? The activation of the
Ras-like GTPase Rap1 by LPS is inhibited by SB202190, suggesting that p38 controls the GTP loading of Rap1. Hackeng et al. have recently
reported that in platelets low-density lipoprotein activates Rap1 and
that this is partially dependent on p38 activation and requires the formation of thromboxane A2
(19). Our preliminary results suggest that thromboxane
A2 production is not required for macrophage spreading in
response to LPS, as the cyclooxygenase inhibitor indomethacin does not
block LPS-induced spreading (A.S. and A.H., unpublished observations).
How might p38 activate Rap1? A simple and attractive possibility would
be that p38 directly phosphorylates a Rap1 GDP/GTP exchange
factor (GEF) and thereby activates Rap1. Several GEFs for Rap1
have been identified to date, and it remains to be determined whether
any of them can be phosphorylated and activated by p38
(64).
Accumulating evidence indicates that the small GTPase Rap1 is
involved in the activation of integrin function in response to a
variety of stimuli. Caron et al. have shown that Rap1 mediates the
activation of phagocytosis via M2-integrin (complement receptor 3) following macrophage stimulation with LPS, phorbol myristate acetate, tumor necrosis factor alpha, and platelet-activating factor
(6). Furthermore, SPA-1, a GTPase-activating protein for Rap1, negatively regulates cell adhesion of HeLa cells to fibronectin (57). Rap1 also controls CD31-stimulated
T-cell adhesion to ICAM and VCAM via LFA-1 (L2) and VLA-4
(41), respectively (51). Our data show that Rap1
mediates LPS-induced 2-integrin-dependent spreading of macrophages.
This suggests that Rap1 is a general activator of integrin function.
The mechanism by which Rap1 controls integrin function is not known.
Rap1 might regulate integrin clustering, integrin affinity, or integrin
interaction with the cytoskeleton. Several effectors for Rap1 have been
isolated including several RalGEFs, B-raf, Krit1, and AF6 (39,
53, 64). Whether any of them is involved in the control of
integrin activation has yet to be shown.
2-integrins play a crucial role in mediating leukocyte adhesion to
endothelial cells and the migration into tissues. This is most clearly
highlighted by the leukocyte adhesion deficiency disease (LAD), in
which leukocytes are deficient in 2-integrin expression and thus are
defective in adhesion (1). Patients with LAD suffer from
recurrent severe bacterial infections. On the other hand, however,
enhanced adhesion of leukocytes as stimulated by LPS during septic
shock can lead to vascular and tissue damage and thereby contribute to
the development of multiple organ failure (30). In
this study we have identified several components of the signaling
pathway leading to increased 2-integrin-dependent adhesion and
spreading of macrophages in response to LPS. These results may prove
important in the development of therapies to fight conditions such as
septic shock.
| |
ACKNOWLEDGMENTS |
We thank J. Bos, R. Davis, C. von Eichel-Streiber, D. Goeddel, S. Moss, M. Muzio, E. Nishida, H. Nishitoh, and A. Self for reagents and
DNA constructs, and members of the lab for valuable discussion.
A.S. is the recipient of an EMBO long-term fellowship. E.C. is
supported by the Wellcome Trust. A.H. thanks the Cancer Research Campaign (UK) for generous support.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: MRC Laboratory
for Molecular Cell Biology, University College London, Gower St.,
London WC1E 6BT, United Kingdom. Phone: 44 (0)20 7679 7909. Fax: 44 (0)20 7679 7805. E-mail: alan.hall{at}ucl.ac.uk.
| |
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Abstract
Introduction
