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Infection and Immunity, August 1999, p. 3824-3829, Vol. 67, No. 8
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Lipopolysaccharide-Induced Tumor Necrosis Factor
Alpha Production by Human Monocytes Involves the
Raf-1/MEK1-MEK2/ERK1-ERK2 Pathway
Tjomme
van der
Bruggen,1
Suzanne
Nijenhuis,1
Estia
van
Raaij,1
Jan
Verhoef,1 and
B.
Sweder
van Asbeck2,*
Eijkman-Winkler Institute for Microbiology,
Infectious Diseases and Inflammation1 and
Department of Internal Medicine, University Hospital
Utrecht,2 Utrecht, The Netherlands
Received 7 December 1998/Returned for modification 18 February
1999/Accepted 6 May 1999
 |
ABSTRACT |
During gram-negative sepsis, human monocytes are triggered to
produce large quantities of proinflammatory cytokines such as tumor
necrosis factor alpha (TNF-
) in response to endotoxin
(lipopolysaccharide [LPS]). Several studies have identified signal
transduction pathways that are activated by LPS, including activation
of nuclear factor-
B (NF-B) and activation of mitogen-activated
protein kinases (MAPKs), including ERK1 and ERK2, c-Jun N-terminal
kinase, and p38. In this study, the relevance of ERK1 and ERK2
activation for LPS-induced TNF- production by primary human
monocytes has been addressed with PD-098059, which specifically blocks
activation of MAPK kinase (MEK) by Raf-1. TNF- levels in the
monocyte culture supernatant, induced by 10 ng of LPS/ml, were reduced
by PD-098059 (50 µM). In addition, PD-098059 also reduced TNF-
mRNA expression when cells were stimulated for 1 h with LPS. On
the other hand, LPS-induced interleukin-10 (IL-10) levels in the
monocyte supernatant were only slightly inhibited by PD-098059. Ro
09-2210, a recently identified MEK inhibitor, completely abrogated
TNF- levels at nanomolar concentrations. IL-10 levels also were
strongly reduced. To show the efficacy of PD-098059 and Ro 09-2210, ERK1 and -2 activation was monitored by Western blotting with an
antiserum that recognizes the phosphorylated (i.e., activated) forms of
ERK1 and ERK2. Addition of LPS to human monocytes resulted in
activation of both ERK1 and ERK2 in a time- and concentration (50%
effective concentration between 1 and 10 ng of LPS/ml)-dependent
manner. Activation of ERK2 was blocked by PD-098059 (50 µM), whereas
ERK1 seemed to be less affected. Ro 09-2210 completely prevented
LPS-induced ERK1 and ERK2 activation. LPS-induced p38 activation also
was prevented by Ro 09-2210. These data further support the view that the ERK signal transduction pathway is causally involved in the synthesis of TNF- by human monocytes stimulated with LPS.
| |
INTRODUCTION |
One of the most potent stimuli for
monocytes is bacterial endotoxin (lipopolysaccharide [LPS]), which is
derived from the outer cell wall of gram-negative bacteria. In response
to LPS, monocytes produce large quantities of proinflammatory
cytokines, including tumor necrosis factor alpha (TNF-),
interleukin-1 (IL-1), and IL-6, followed by the production of IL-10,
which has anti-inflammatory properties (6, 22). Many studies
have shown that these cytokines play a pivotal role in the pathogenesis
of bacterial sepsis, although the precise function of each cytokine
individually remains to be elucidated (8, 11, 31).
At low LPS concentrations (
100 ng/ml), LPS binding to monocytes is
mediated by CD14 and LPS-binding protein, a serum-derived protein which
facilitates binding to CD14 (28). Although CD14 is
indispensable for LPS signaling, membrane-bound CD14 is a
nontransmembrane molecule linked to the plasma membrane by a
glycosylphosphatidyl inositol anchor. LPS signaling is therefore
possibly mediated by a putative second transmembrane molecule, some
candidates for which have been described previously (29).
Alternatively, LPS is internalized (2) and may act as a
second messenger itself, since it has remarkable similarity to ceramide
(32).
As demonstrated in several studies, LPS induces many intracellular
responses, including activation of nuclear factor-B (NF-B) and
activation of members of the mitogen-activated protein kinase (MAPK)
family (25). As tested in various cell types, LPS can induce
activation of extracellular-signal-regulated kinase-1 (ERK1) and ERK2
(3, 18), c-Jun N-terminal kinases (JNKs) (13, 23), and p38 (14, 23). Activation of p38 is necessary
for production of TNF-, as demonstrated by use of the specific p38 inhibitor SB 203580 (16). More recently, it was demonstrated that JNK is involved in TNF- translation (24). Studies
with the murine macrophage cell line RAW 264.7, in which Raf-1 is
either activated as an estrogen receptor-Raf-1 hybrid or blocked by
dominant negative Raf-1 or Ras, suggest that the
Raf-1/MEK1-MEK2/ERK1-ERK2 pathway is involved in TNF- production
(10, 12).
In the present study, we have tested the effect of PD-098059 (which
specifically blocks MAPK kinase [MEK] activation by Raf-1 [1]) on LPS-induced TNF- production by primary
human monocytes, since such experiments provide information concerning
the role of the ERK pathway in a system which is relevant to human
sepsis. PD-098059 reduced TNF- protein levels and TNF- mRNA
expression in a dose-dependent manner. On the other hand, IL-10 protein
levels were slightly affected. The inhibitory effect of PD-098059 on LPS-induced activation of ERK1 and ERK2 was also seen. Ro 09-2210, a
MEK inhibitor which blocks activation of ERK1 and -2, but also JNK and
p38, was even more potent and completely abrogated TNF- levels. In
addition, this compound blocked IL-10. These data indicate that in
human monocytes TNF- production requires activation of the ERK
pathway and suggest that IL-10 synthesis is under control of JNK and/or p38.
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MATERIALS AND METHODS |
Reagents.
LPS (from Salmonella typhimurium) was
obtained from Sigma, St. Louis, Mo. Enzyme-linked immunosorbent assays
(ELISAs) for human TNF- and IL-10 were from the Central Laboratory
for Blood Transfusion, Amsterdam, The Netherlands. Trizol, reverse
transcriptase (Superscript), and RPMI 1640 were purchased from Life
Technologies (Gaithersburg, Md.). Deoxynucleoside triphosphates
(dNTPs), biotinylated primers, and digoxigenin-labeled probes for
TNF- and GAPDH (glyceraldehyde-3-phosphate dehydrogenase) were
supplied by Pharmacia (Uppsala, Sweden). Random hexamer primers, DNase
I (RNase free), and the digoxigenin detection fluorescence ELISA kit
were obtained from Boehringer (Mannheim, Germany). RNase inhibitor and
Taq DNA polymerase were from Promega (Madison, Wis.),
whereas PD-098059 (2'-amino-3'-methoxyflavone) was obtained from Biomol
Research Laboratories (Plymouth Meeting, Pa.). The ERK1-ERK2 or p38
phosphospecific antibodies purified from rabbit antiserum were
purchased from New England BioLabs (Beverly, Mass.). Polypropylene
materials were manufactured by Costar, Cambridge, Mass. (96-well
plates) or Becton Dickinson Labware, Lincoln Park, N.J. (14-ml
round-bottom tubes). Ro 09-2210 was kindly donated by T. Murray, Roche
Products Limited, Hertfordshire, United Kingdom.
Isolation of monocytes.
Human monocytes were isolated from
the buffy coat obtained from informed healthy volunteers at the
Bloodbank Utrecht. First, peripheral blood mononuclear cells were
separated from the polymorphonuclear leukocyte fraction by
centrifugation (1,000 × g, 20 min, room temperature)
of the buffy coat (containing 6.5 mM sodium citrate) layered on Ficoll
(1.078 g/ml) in Leuco Sep tubes (Greiner). Next, monocytes were
purified from peripheral blood mononuclear cells by countercurrent
elutriation as described before (7). For our experiments,
the >80% pure monocyte cell fractions (viability, >95%) were used.
Cell culture conditions.
Monocytes were cultured in RPMI
1640 supplemented with 4% A+B+ serum, or with 10% fetal calf serum
(for PD-098059 experiments followed by ELISA), and gentamicin (10 µg/ml). Cells were warmed for 15 min at 37°C in a 5%
CO2 incubator before treatment with PD-098059 or Ro 09-2210 for 30 min at 37°C. After preincubation, monocytes were stimulated
with 10 ng of LPS per ml for different time periods in 96-well
polypropylene plates (200 µl/well; 1.5 × 106
cells/ml). The supernatants were collected and stored at 
20°C until
TNF-- or IL-10-specific ELISAs were performed. Cells used for
Western blotting were incubated in polypropylene tubes (1 ml/tube;
2 × 106 cells/ml).
Reverse transcriptase PCR.
Cells (1.5 × 106/ml) were stimulated with 10 ng of LPS per ml in the
presence or absence of PD-098059 for 1 h at 37°C in 14-ml polypropylene tubes. Total RNA was isolated from 107
monocytes/sample with Trizol. In brief, cell pellets were lysed with 1 ml of Trizol for 10 min at room temperature. After treatment with 0.2 ml of chloroform for 2 min, the samples were centrifuged (10,000 × g) for 15 min at 4°C. RNA was precipitated from the aqueous phase with 0.5 ml of isopropanol (10 min, room temperature) and
pelleted by centrifugation (10,000 × g) at 4°C for
10 min. The pellet was washed with 70% ethanol and dissolved in 100 µl of diethylpyrocarbonate (DEPC)-treated water. Possible
contamination of the total RNA with genomic DNA was excluded by DNase
treatment for 15 min at 37°C. RNA was repurified by
phenol-chloroform-isoamyl alcohol extraction, precipitated with 70%
ethanol, and dissolved in DEPC-treated water (50 µl). Before cDNA
synthesis, RNA samples were used for a 40-cycle PCR with GAPDH primers
to confirm the absence of contaminating DNA. cDNA was prepared by
adding 1 µg of total RNA to a mixture (final volume, 25 µl)
containing 200 U of reverse transcriptase, 50 mM Tris-HCl (pH 8.3), 75 mM KCl, 3 mM MgCl2, 8 mM dithiothreitol, 0.5 mM dNTPs, 80 nmol of random hexamer primers, and 20 U of RNase inhibitor at 37°C
for 1 h. After the reaction, the volume was adjusted with
DEPC-treated water to 200 µl/µg of RNA initially used. PCR was
performed with primer pairs for human TNF- or GAPDH (Table
1). The primer pairs contained one
biotinylated primer to enable further quantification of the PCR
products with a digoxigenin detection ELISA. For each PCR, 5 µl of
cDNA was added to a mixture (final volume, 25 µl) containing 0.5 U of
Taq DNA polymerase, 0.4 mM dNTPs, 10 mM Tris-HCl (pH 9.0),
50 mM KCl, 0.1% Triton X-100, 2 mM MgCl2, and 0.2 µM primers. PCR was carried out on a thermal cycler (Perkin-Elmer, Norwalk, Conn.) for 25 cycles (GAPDH) or 29 cycles (TNF-), with a
single cycle consisting of 1 min at 94°C (denaturation), 1 min at
60°C (annealing), and 2 min at 72°C (extension). The final cycle
was completed with an additional extension of 10 min at 72°C.
Biotinylated PCR products were quantified with a digoxigenin detection
fluorescence ELISA. For each sample, 5 µl of PCR products containing
the biotinylated strands was incubated with 1.25 µl of denaturation
buffer (200 mM NaOH, 40 mM EDTA [final concentrations]) for 5 min at
room temperature. Subsequently, denaturation was stopped with 6.25 µl
of neutralization buffer (75 mM Na2HPO4 [final concentration], pH 6.0) before 200 µl of hybridization buffer (62.5 mM Na2HPO4, 0.94 M NaCl, 94 mM citric acid, 10 mM MgCl2, 0.125% Tween 20, and 0.0625% bovine serum
albumin [final concentrations], pH 6.5) containing 20 ng of
digoxigenin-labeled probes (Table 1) per ml was added. Samples were
then transferred to streptavidin-coated eight-well strips, and the
assay was carried out according to the instructions of the
manufacturer. Fluorescence was measured on a Cytofluor II meter
(PerSeptive Biosystems, Framington, Mass.) at excitation and emission
wavelengths of 450 and 550 nm, respectively. Signal intensities of
TNF- fluorescence were corrected for background (PCR product
omitted, probe present) and subsequently normalized with GAPDH values
corrected for the background.
Measurement of ERK1 and -2 and p38 activation.
To monitor
ERK1 and -2 activation, sodium dodecyl sulfate (SDS)-polyacrylamide gel
electrophoresis was performed, followed by Western blotting with a
purified rabbit antiserum containing antibodies directed against
Thr202- and Tyr204-phosphorylated (i.e., active) ERK1 (p44) and ERK2
(p42) or Thr180- and Tyr182-phosphorylated p38.
First, monocytes (1.5 × 106 cells/ml) were
preincubated for 30 min with PD-098059 (50 µM) or Ro 09-2210 (10 to
1,000 nM) at 37°C before stimulation with LPS (10 ng/ml or the
indicated concentrations) at 37°C for the indicated times. After
incubation, the cells (2 × 106/sample) were washed
with ice-cold phosphate-buffered saline and resuspended in 80 µl of
lysis buffer (1% Triton X-100, 50 mM Tris-HCl [pH 8.0], 100 mM NaCl)
containing several inhibitors (1 µg of antipain per ml, 2 µg of
benzamidine per ml, 1 µg of leupeptin per ml, 1 µg of chymostatin
per ml, 1 µg of pepstatin A per ml, and 1 mM phenylmethylsulfonyl
fluoride). After addition of 20 µl of 5× sample buffer (final
concentrations of 2% SDS, 2% 
-mercaptoethanol, and 10% glycerol
in 300 mM Tris-Cl, pH 6.8), the lysates were boiled for 2 min. Samples
were run on a 10% polyacrylamide minigel for 1 h at 150 V and
blotted for 2 h (50 V) on a 0.45- µm-pore-size polyvinylidene
difluoride (PVDF) membrane at 4°C. The PVDF membrane was blocked with
0.6% bovine serum albumin (in Tris-buffered saline-Tween 20 [TBST]
plus 1 mM EDTA) for 1 h at room temperature and subsequently incubated for 1 h with the ERK1 and -2 or p38 phosphospecific rabbit antibodies diluted (1:2,000 in blocking buffer). After being
washed six times with TBST for 3 min, the PVDF membrane was incubated
at room temperature for 2 h with goat anti-rabbit-peroxidase conjugate (1:8,000 in blocking buffer). The PVDF filter was again washed six times with TBST and then twice with phosphate-buffered saline for 5 min. Thereafter, proteins were visualized with enhanced chemiluminescence on film (Kodak X-OMAT LS).
| |
RESULTS |
Effect of PD-098059 and Ro 09-2210 on LPS-induced TNF-
production.
To activate TNF- production, human monocytes were
incubated with LPS (10 ng/ml). Addition of various concentrations of
PD-098059 (a specific inhibitor of the ERK1-ERK2 pathway) reduced
TNF- levels in a dose-dependent manner (Fig.
1A). Also, when measured at different
incubation intervals (i.e., 1, 2, 4, and 20 h), LPS-induced TNF- levels were reduced by 50 µM PD-098059 (data not shown).
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FIG. 1.
Effect of PD-098059 and Ro 09-2210 on LPS-induced
TNF- levels in human monocyte culture supernatant. (A) Human
monocytes (1.5 × 106 cells/ml) were preincubated with
the indicated concentrations of PD-098059 for 30 min and subsequently
treated with buffer (white bars) or 10 ng of LPS per ml (black bars)
for 20 h at 37°C. (B) Cells were incubated with the indicated
concentrations of Ro 09-2210 for 30 min before treatment with 10 ng of
LPS/ml for 4 h. Supernatants were collected for a TNF- ELISA.
Results are mean values from five independent experiments ± standard errors. *, significant difference (P < 0.05) by repeated-measures analysis of variance followed by the
Newmans-Keuls test.
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We next tested the effect of a different MEK inhibitor, Ro 09-2210. This fungal compound is an inhibitor of several MEKs,
including MKK1,
-4, -6, and -7 and SEK, but downstream kinases
such as JNK, p38, and
MAPKAP1 and -2 are not inhibited directly
(
18a). However,
MKK1 seems to be the most sensitive kinase for
inhibition by Ro 09-2210 (fourfold lower 50% inhibitory concentrations).
Interestingly,
LPS-induced TNF-
levels were completely eliminated
by nanomolar
concentrations of Ro 09-2210 (Fig.
1B). In the absence
of LPS
stimulation, the effect of Ro 09-2210 was minimal (data
not
shown).
We then evaluated the effect on LPS-induced TNF-
mRNA expression, to
examine at which level PD-098059 interferes with TNF-
synthesis.
Reverse transcriptase PCR fragments for TNF-
were
quantified with a
fluorescence ELISA by using a digoxigenin-labeled
TNF-
probe.
LPS-induced TNF-
mRNA levels were reduced to background
expression
(unstimulated cells) by 50 µM PD-098059 (Fig.
2), showing
that the inhibitory effect of
PD-098059 is found at the level
of transcription and/or mRNA
stabilization.
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FIG. 2.
Effect of PD-098059 on LPS-induced TNF- mRNA
expression in human monocytes. Human monocytes were pretreated with
PD-098059 (50 µM, 30 min) and subsequently incubated with buffer
(white bars) or 10 ng of LPS/ml (black bars) for 1 h. Thereafter,
reverse transcriptase PCR was performed on RNA isolates, and PCR
fragments were quantified with a digoxigenin-labeled probe as described
in Materials and Methods. Results are expressed as fold induction
[(TNF-x/GAPDHx)/(TNF-control/GAPDHcontrol)].
Results are expressed as the means from four independent
experiments ± standard errors. *, significant difference
(P < 0.05) by Student's t test for paired
samples.
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Effect of PD-098059 and Ro 09-2210 on LPS-induced IL-10
production.
LPS stimulation of human monocytes results in the
release of several cytokines that interact in complex autocrine and
paracrine regulatory mechanisms. To test whether the inhibitory effect
of PD-098059 or Ro 09-2210 could be shown for other cytokines, the effect of IL-10 synthesis was monitored. IL-10 levels in monocyte supernatants taken after 20 h of incubation with LPS (10 ng/ml) were measured by ELISA. IL-10 levels were inhibited by PD-098059 (Fig.
3A), but the effect was small compared to
the decrease in TNF- levels (Fig. 1A). We conclude, therefore, that
the inhibitory effect of PD-098059 on TNF- synthesis cannot be
extrapolated in a quantitative way to cytokine production in general.
On the other hand, IL-10 levels were considerably reduced by Ro 09-2210 (Fig. 3B).
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FIG. 3.
Effect of PD-098059 and Ro 09-2210 on LPS-induced IL-10
levels in human monocyte culture supernatant. Elutriated human
monocytes (1.5 × 106 cells/ml) were preincubated with
various concentrations of PD-098059 (A) or Ro 09-2210 (B) for 30 min at
37°C, followed by a 20-h incubation with buffer (white bars) or 10 ng
of LPS/ml (black bars). IL-10 ELISA was performed with culture
supernatants, and data are expressed as means from five (A) or three
(B) independent experiments ± standard errors. *, significant
difference (P < 0.05) by repeated-measures analysis of
variance followed by the Newmans-Keuls test.
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Effect of PD-098059 and Ro 09-2210 on LPS-induced ERK1 and ERK2
activation.
In several experimental systems it has been
demonstrated that LPS induces activation of ERK2 (3, 18,
25). However, most experiments are conducted with the murine
macrophage cell line RAW 264.7, which responds to high concentrations
of LPS. In this study, we show activation of both ERK1 and ERK2 after addition of LPS to human monocytes (by Western blotting with a phosphospecific ERK1-ERK2 antiserum). Activation by 10 ng of LPS per ml
was transient, with an apparent maximal effect at approximately 20 min
(Fig. 4). Importantly, the activation was
modest compared to the effect of phorbol myristate acetate (PMA) (80 ng/ml, 5 min) or N-formyl-methionyl-leucyl-phenyalanine (1 µM, 2 min). Moreover, the fMLP-induced ERK2 activation much more
rapid (maximum at 2 min) than the activation induced by LPS (Fig. 4).
The effect of LPS was concentration dependent (50% effective
concentration of between 1 and 10 ng/ml) (Fig.
5A), and pretreatment with PD-098059 (50 µM) almost completely blocked activation of ERK2 when monocytes were
incubated with 1 or 10 ng of LPS/ml (Fig. 5A). Interestingly, LPS-induced ERK1 activation appeared to be less affected by PD-098059. When very high LPS concentrations (100 and 1,000 ng of LPS/ml) were
used, no inhibitory effect of PD-098059 was observed. Ro 09-2210 also
prevented activation of both ERK1 and ERK2 in a dose-dependent manner
when monocytes were stimulated with 10 ng of LPS/ml for 15 min (Fig.
5B).
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FIG. 4.
Effect of LPS on ERK1 and ERK2 activation in human
monocytes. Cells (2 × 106 cells/sample) were
incubated with 10 ng of LPS/ml, 1 µM fMLP, or 80 ng of PMA/ml for the
indicated times. Samples were analyzed by SDS-polyacrylamide gel
electrophoresis and Western blotting with an ERK1-ERK2 phosphospecific
antibody which recognizes only the activated forms of ERK1 and ERK2.
ERK1 appears as the upper band (44 kDa); ERK2 appears as the lower band
(42 kDa). The depicted data are typical of those from three independent
experiments.
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FIG. 5.
Effect of PD-098059 on LPS-induced activation of ERK1
and ERK2 in human monocytes. (A) Human monocytes were preincubated for
30 min with buffer or 50 µM PD-098059, followed by a 15-min
incubation with the indicated concentrations of LPS. (B) To test the
effect of Ro 09-2210, cells were preincubated with the indicated
concentrations of Ro 09-2210 for 30 min at 37°C before activation
with 10 ng of LPS/ml for 15 min. ERK1 and -2 activation was determined
by Western blotting with an ERK1-ERK2 phosphospecific antibody. ERK1
appears as the upper band (44 kDa); ERK2 appears as the lower band (42 kDa). Results are representative of those from two independent
experiments.
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Effect of Ro 09-2210 on LPS-induced p38 activation.
As
mentioned before, Ro 09-2210 inhibits multiple MEKs. To test if the
multiple inhibitory effect of Ro 09-2210 can be extended to human
monocytes, we investigated LPS-induced p38 activation in the presence
of Ro 09-2210. To monitor p38 activation, Western blotting was carried
out with phosphospecific p38 antibodies that interact only with
activated p38. As shown in Fig. 6, Ro
09-2210 blocked activation of p38 in a dose-dependent manner. At
concentrations of 50 nM and higher, a strong reduction of p38
activation is observed, which is in the same range as the
concentrations necessary to decrease TNF- and IL-10 levels (Fig. 1B
and 3B).
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FIG. 6.
Effect of Ro 09-2210 on LPS-induced p38 activation in
human monocytes. Human monocytes (2 × 106
cells/sample) were preincubated with various concentrations of Ro
09-2210 for 30 min at 37°C. After stimulation with 10 ng of LPS/ml
for 15 min, samples were lysed and used for Western blotting with p38
phosphospecific polyclonal antibodies that recognize the activated form
of this MAPK.
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DISCUSSION |
In this study, we show that the ERK pathway is involved in the
production of TNF- by LPS-stimulated human monocytes. Addition of
LPS resulted in the transient (maximum at ~20 min) and dose-dependent (50% effective concentration of between 1 and 10 ng/ml) activation of
ERK1 and ERK2. Although LPS is a very potent stimulus for human monocytes, activation of ERK1 and ERK2 was modest compared to effects
of fMLP and PMA. This suggests that only a small fraction of total ERK1
and ERK2 is utilized by LPS to activate human monocytes. Activation of
ERK2 and, to a lesser extent, ERK1 was reduced by PD-098059, an
inhibitor of MEK-1 activation by Raf-1 (1). Previous studies
had demonstrated the importance of the ERK pathway for TNF-
synthesis in the murine macrophage cell line RAW 264.7 by manipulation
of Ras or Raf-1. Moreover, LPS-induced TNF- synthesis in rat primary
astrocytes is also blocked by PD-098059 (4). The need for
activation of the ERK pathway is not restricted to LPS, since Fc
receptor-induced TNF- mRNA accumulation is also inhibited by
PD-098059 in THP-1 and NK cells (27). Theoretically, the ERK
pathway is coupled to TNF- production, because activated ERK
phosphorylates the ternary complex factor Elk-1, resulting in increased
transcription of c-Fos and hence enhanced formation of AP-1
(15). The TNF- promoter contains several AP-1-binding regions (tetradecanoyl phorbol acetate response elements)
(26) and is therefore potentially regulated by AP-1.
JNK and p38 also are activated in response to LPS (13, 14,
23). These additional MAPK signaling pathways are reported to
regulate TNF- mRNA translation (16, 24). Interestingly, Ro 09-2210 inhibits the ERK1 and -2, JNK, and p38 pathways
simultaneously (18a). In our hands, LPS-induced activation
of p38 was also blocked by Ro 09-2210 in human monocytes. This suggests
that Ro 09-2210 prevents both TNF- transcription and translation.
This could explain the complete inhibitory effect of Ro 09-2210 on
TNF- levels, whereas PD-098059 was partially effective.
Combined with the well-established role of NF-B, it appears that
TNF- production is regulated in a complex manner, involving several
signal transduction pathways working together. In addition, in one
study it was reported that PD-098059 inhibits LPS-induced activation of
NF-B (20), suggesting cross-talk between the signaling
pathways. Similar to findings reported by Foey et al. (9),
IL-10 production was only slightly affected by the ERK pathway
inhibitor. This suggests that expression of TNF- is regulated differently from that of IL-10, although some caution is necessary, since the difference between the TNF- and IL-10 reductions was found
only with 50 µM PD-098059. The TNF- and IL-10 promoters differ in
many aspects, including the absence of an NF-B binding site in the
human IL-10 promoter and the presence of a cyclic AMP response element
(21, 26). The IL-10 promoter contains a putative AP-1
recognition site (21). However, the minor sensitivity of
LPS-induced IL-10 production to PD-098059 suggests that ERK1- and
-2-induced AP-1 synthesis is not essential under these experimental conditions. On the other hand, IL-10 production is inhibited by the
specific p38 inhibitor SB203580, indicating that p38 activation is
involved (5, 9). This could explain the inhibitory effect of
Ro 09-2210 on IL-10 levels, since Ro 09-2210 also blocks p38. It is
possible that inhibition of JNK by Ro 09-2210 is linked to down
regulation of TNF- and IL-10. Unfortunately, to our knowledge no
specific JNK pathway inhibitor which could further help to delineate
the role of JNK has been described.
Endogenously produced TNF- is important for the subsequent synthesis
of IL-10 by human monocytes through autocrine and paracrine mechanisms
(30). Therefore, reduction of TNF- levels by PD-098059 should theoretically result in decreased IL-10 synthesis. However, as
mentioned before, PD-098059 had little inhibitory effect on IL-10
levels. An explanation for this discrepancy is that TNF- levels are
not totally reduced by PD-098059. The remaining TNF- production
could be sufficient for autocrine stimulation of monocytes to produce
IL-10.
Based on the data presented in this and other studies, the ERK pathway
is a potential therapeutic target for treatment and prevention of
bacterial sepsis in which excessive TNF- production occurs. First,
inhibition of the ERK pathway results in reduced TNF- levels.
Second, our results and those of others (9) suggest that the
ERK signal transduction route is selective, because IL-10 is less
sensitive to inhibition of this pathway. This could be favorable, since
IL-10 promotes LPS hyporesponsiveness of human monocytes
(22), which may contribute to dampen the hyperactivated immune system during sepsis.
In addition, blocking the ERK pathway could be potentially interesting
for the treatment of other diseases, such as psoriasis, atherosclerosis, and cancer (17). Pretreatment of mice with the tyrosine kinase inhibitor AG 126 protected against a lethal dose of
LPS (19). In this study, protection correlated with reduction of serum TNF- levels and in vitro with inhibition of ERK2.
The use of PD-098059 is even more attractive because of the high
specificity of this compound for the ERK pathway. However, our
preliminary experiments indicated that PD-098059 did not inhibit LPS-stimulated TNF- production in whole blood, probably due to neutralization by plasma (data not shown). Due to the maximal solubility limit, it was not possible to raise the dose of PD-098059 in
order to overcome the neutralizing effect. In this respect, Ro 09-2210 seems to be more promising, since this compound reduced LPS-induced
TNF- production in whole blood, although 100-fold-higher concentrations were needed compared to those in experiments with isolated cells (data not shown). However, Ro 09-2210 also inhibits IL-10 levels, which could be a disadvantage.
In conclusion, the complex regulation of LPS-induced TNF- production
by human monocytes involves activation of ERK1, ERK2, and parallel
cascades leading to activation of JNK and p38. Improved knowledge of
the mechanisms that control TNF- production could expand the
therapeutic possibilities for interference with inflammatory responses
in a more specific way.
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ACKNOWLEDGMENTS |
We are grateful to Machiel de Vos and Jeena Middel for isolation
of human monocytes and to Leonie Boven for establishing the TNF-
reverse transcriptase PCR. Karel Zuur and Ian Leistikow are gratefully
acknowledged for performing whole-blood experiments with PD-098059, and
T. Murray is gratefully acknowledged for donating Ro 09-2210.
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FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Internal Medicine, Room F02.126, University Hospital Utrecht, P.O. Box 85500, 3508 GA Utrecht, The Netherlands. Phone: 31 30 2509111. Fax: 31 30 2523741. E-mail: B.S.vanAsbeck{at}digd.azu.nl.
Editor:
R. N. Moore
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Infection and Immunity, August 1999, p. 3824-3829, Vol. 67, No. 8
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
