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Clinical and Diagnostic Laboratory Immunology, November 1999, p. 878-884, Vol. 6, No. 6
1071-412X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Role of p38 in the Priming of Human Neutrophils by
Peritoneal Dialysis Effluent
Ian
Daniels,*
John
Fletcher, and
Andrew Paul
Haynes
Medical Research Centre, City Hospital,
Nottingham, United Kingdom
Received 17 May 1999/Returned for modification 21 June
1999/Accepted 1 September 1999
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ABSTRACT |
Peritoneal dialysis effluent (PDE) contains a low-molecular-weight
substance that is able to prime human neutrophils for the release of
arachidonic acid and superoxide anion. Conventional priming agents,
such as tumor necrosis factor alpha (TNF-
), are known to signal via
mitogen-activated protein (MAP) kinases; at least one possible
substrate for MAP kinases is cytosolic phospholipase A2
(cPLA2). Phosphorylation of this enzyme results in
arachidonic acid release, and this fatty acid is a potent primer and
activator of the human neutrophil NADPH oxidase. Because of the
striking similarities between the priming of neutrophils with agents
such as TNF- and PDE, we have investigated the signalling pathways evoked by PDE and explored the possibility that cPLA2 is a
target for activated MAP kinases. Our results show that PDE treatment of human neutrophils results in the phosphorylation of the p38 kinase
rather than the p42 and p44 kinases. Phosphorylation of p38 is
transient with maximal activity being observed 1 min after exposure to
PDE. We were unable to demonstrate that activation of p38 resulted in
phosphorylation of cPLA2; furthermore, translocation of
this enzyme to a membrane-containing fraction was not enhanced in
PDE-treated neutrophils. Taken together, these data suggest that, in a
manner similar to that of TNF-, PDE primes human neutrophils by the
activation of the p38 kinase. However, unlike the cytokine, the
activation of this protein does not result in phosphorylation or
activation of cPLA2.
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INTRODUCTION |
The intracellular signalling
pathways utilized by priming agents, such as lipopolysaccharide (LPS),
tumor necrosis factor alpha (TNF-), and granulocyte-macrophage
colony-stimulating factor (GM-CSF), have recently become an area of
intense study. An increasing body of evidence has been presented to
suggest that all of these priming agents act by signalling through the
mitogen-activated protein (MAP) kinase cascade (10, 24, 32, 33,
37). MAP kinases are proline-directed serine-threonine protein
kinases that are activated by phosphorylation upon threonine and
tyrosine residues in a Thr-X-Tyr motif that is found in an activation
loop proximal to the ATP and substrate binding sites. There are three main classes of MAP kinases: the erk, c-jun
N-terminal, and p38 kinases. All three groups differ in size of the
activation loop and nature of the X amino acid in the Thr-X-Tyr motif
(i.e., Glu in the erk kinases, Pro in the c-jun
kinases, and Gly in p38). Signalling through this cascade by priming
agents appears to involve one of two pathways: treatment of cells with
GM-CSF appears to phosphorylate erkI/II (32),
while LPS and TNF- treatment results in phosphorylation of p38
(10, 24, 32, 33, 37). Although many substrates for
erkI/II and p38 have been identified in vitro (for a review,
see reference 21), the exact pathway from MAP kinase
activation to a functional cellular response (e.g., priming) has yet to
be elucidated. One suggested route has been via phosphorylation and/or
translocation of the 85-kDa cytosolic phospholipase A2 (cPLA2) (16). Phosphorylation and subsequent
translocation of this enzyme results in arachidonic acid release
(9), and it is well documented that this fatty acid is able
to both prime and directly activate the NADPH oxidase in human
neutrophils (5, 12, 27). We have previously reported a novel
priming agent present in peritoneal dialysis effluent (PDE) that is a
potent primer of NADPH oxidase activity and arachidonic acid release in
human neutrophils (6, 17). In this study, we have
investigated the MAP kinase cascade utilized by this priming agent and
explored the possibility that its effects upon the NADPH oxidase are
mediated through the phosphorylation of cPLA2.
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MATERIALS AND METHODS |
Reagents.
Polyclonal anti-p38 and anti-erkII MAP
kinases were purchased from Santa Cruz Biotechnology Inc., Santa Cruz,
Calif. and anti-phospho-specific p38 and anti-phospho-specific
erkI/II were purchased from Calbiochem, Nottingham, England.
Polyclonal cPLA2 was a kind gift from Astra Charnwood,
Leics, England, and SB203580, SB203590, PD-098,059, and genistein were
purchased from Alexis Corporation, Nottingham, England. All other
reagents, unless otherwise stated, were purchased from Sigma Chemical
Company, Poole, Dorset, England.
Preparation of neutrophils.
Human peripheral blood
neutrophils were prepared by standard methods (3). Fresh
venous blood was taken into EDTA (dipotassium salt) to give a final
concentration of 3.5 mM. Erythrocytes were sedimented on dextran, and
the leukocyte-rich plasma was further purified over a Ficoll gradient
(lymphocyte separation medium; Flow Laboratories, Herts, England). The
neutrophil-rich pellet was subjected to hypotonic lysis to remove
remaining erythrocytes and washed twice in phosphate-buffered saline
(PBS; pH 7.4). Purification of cells by this method routinely gave
preparations of >99% viability, as assessed by trypan blue exclusion,
and >97% purity, as assessed by examination of stained cytospin
preparations. Cells were counted in a hemocytometer and suspended at a
concentration of 1 × 108 ml
1.
PDE.
Six PDEs (1.36%; Dianeal; Baxter Travenol Inc.,
Chicago, Ill.) were obtained from patients receiving continuous
ambulatory peritoneal dialysis (CAPD) after an intraperitoneal dwell of
4 h. All patients had been established on CAPD for more than 2 months, were not suffering infection, and had not received antibiotic therapy over the preceding 4 weeks. PDE was stored at 
70°C until required. Before use, PDE was filtered through a 0.2-µm-pore-size membrane and the pH was adjusted to 7.4 by the addition of HEPES, to
give a final concentration of 20 mM. The concentrations of creatinine
and urea in PDE were determined by autoanalysis; the concentration of
protein was determined by the method of Lowry et al. (19);
the concentration of endotoxin was determined by the limulus amoebocyte
lysate assay (Sigma diagnostic kit; Sigma Chemical Company); and the
concentrations of TNF- and interleukin 1
were determined by
enzyme-linked immunosorbent assay (ELISA) (R & D Systems, Abingdon,
Oxon, England).
Assay for superoxide.
Superoxide production by neutrophils
was determined by lucigenin-enhanced chemiluminescence in a
plate-reading luminometer (Lumiscan; Labsystems, Basingstoke, England).
The reaction mixture (200 µl) contained 25 µM lucigenin, PBS (pH
7.2), 1 mM CaCl2, 0.7 mM MgCl2, 0.1% (wt/vol)
low endotoxin bovine serum albumin, inhibitor and/or vehicle and
neutrophils to give a final concentration of 1 × 106
ml1. PDEs were routinely used at a concentration of 50%
(vol/vol). Reactions were initiated by the addition of 1 µM
N-formyl-Met-Leu-Phe (fMLP). Superoxide anion formation was
taken as the integral of superoxide dismutase inhibitable light output
over the initial 30 min of the reaction.
Assay of inhibitor toxicity.
The toxicities of PD-098,059,
SB203580, SB203590, genistein, and the vehicle upon the neutrophils
were determined over a 60-min period by ATP bioluminescence
(4). The ability of these compounds to scavenge superoxide
anions was determined by using a xanthine-xanthine oxidase cell-free
system (7).
Preparation of neutrophils for cPLA2 and MAP kinase
analysis.
Neutrophils were incubated with end-over-end rotation at
37°C in either PBS (pH 7.4) containing 1 mM CaCl2, 0.7 mM
MgCl, and 0.1% (wt/vol) low endotoxin bovine serum albumin or PDE
(50% [vol/vol]). In some experiments, cells were also stimulated
with 1 µM fMLP or 100 ng of phorbol myristate acetate (PMA)
ml1. Neutrophils (2 × 107 cell
equivalents) were removed at various time intervals, plunged into 30 ml
of ice-cold PBS, and rapidly pelleted by centrifugation at 4°C
(250 × g for 5 min). The pellet was suspended in 400 µl of ice-cold lysis buffer (50 mM HEPES [pH 7.2] containing 1 mM EDTA, 1 mM EGTA, 1 mM phenylmethylsulfonyl fluoride, 5 mM
dithiothreitol, 1 mM sodium orthovanadate, 1 mM sodium pyrophosphate,
and 100 µl of mammalian cell extract protease inhibitor cocktail
[Sigma Chemical Company] ml1) and disrupted by
sonication on ice (two 10-s bursts/power setting 2; Rapidis 50 cell
disrupter; Ultrasonics, London, England). Cell disruption was confirmed
by light microscopy. Cell homogenates were centrifuged at 250 × g for 15 min at 4°C to remove unbroken cells and cell
debris before further centrifugation at 100,000 × g
for 60 min at 4°C in a Beckman L8M ultracentrifuge. The supernatant (cytosolic fraction) was retained, and the membrane-containing pellet
was suspended in 400 µl of ice-cold lysis buffer containing 0.5%
(vol/vol) Triton X-100. Membrane proteins were solubilized by further
sonication on ice (two 10-s bursts) before filtration through a
0.45-µm-pore-size membrane to remove particulate material (ultrafree
filter units; Millipore, Bedford, Mass.). Protein concentrations were
determined in both cytosol and membrane fractions by the method of
Lowry et al. (19).
Immunoblotting.
Fifty microliters (equivalent to 50 µg of
protein) of cytosol or 100 µl (100 µg of protein) of membrane were
mixed with an equal volume of 4× concentrated Laemmli stopping
solution (62.5 mM Tris-HCl [pH 6.8], 20% [vol/vol] glycerol, 5%
[vol/vol] -mercaptothanol, 2% [wt/vol] sodium dodecyl sulfate,
trace bromophenol blue) and heated at 95°C for 10 min. Samples were
electrophoresed through either 7.5% (cPLA2) or 15% (p38
and erk) polyacrylamide gels. Proteins were transferred to
BioTrace NT nitrocellulose membranes (Gelman Sciences, Northampton,
England) and probed with appropriate antibodies (cPLA2,
p38, phospho-specific p-38, erkII, phospho-specific erkI/II, and horseradish peroxidase-conjugated anti-rabbit
immunoglobulin). Bound antibodies were detected by incubating blots in
SuperSignal (Pierce, Rockford, Ill.), followed by brief exposure to
Hyperfilm (Amersham International, Slough, England). Once visualized,
blots were stripped of the primary antibody-secondary antibody complex by exposure to 62.5 mM Tris-HCl (pH 6.7) containing 100 mM
-mercaptothanol and 2% (wt/vol) sodium dodecyl sulfate for 30 min
at 50°C. Stripped blots were reprobed with primary and secondary
antibodies as required.
Assay of cPLA2.
cPLA2 activity was
measured as previously described (14). The basic reaction
mixture (50 µl) contained 0.5 µM
1-stearoyl-2-[1-14C]arachidonyl-3-L-phosphatidylcholine
(ca. 30,000 dpm), 10 mM CaCl2, and 50 mM Tris-HCl (pH 7.4).
The reaction was initiated by the addition of 100 µg of cytosolic or
membrane protein. Reaction mixtures were incubated at 37°C for 30 min
in a shaking water bath and terminated by the addition of 50 µl of
ice-cold ethanol containing 2% (vol/vol) acetic acid and 1 mg of
arachidonic acid ml1.
A 50-µl portion of extract was spotted onto thin-layer plates
(Linnear K Silica Gel 60; Whatman Inc., Clifton, N.J.) that had been
dipped in 1 mM EDTA, air dried, and activated by heating at 110°C for
60 min. Plates were developed twice in a saturated environment of the
organic phase of ethyl acetate:isoctane:water:acetic acid (55:75:100:8
[vol/vol]). Arachidonic acid was visualized by brief exposure of the
plates to iodine vapors. The area of silica corresponding to the fatty
acid was removed, 4.0 ml of scintillation fluid (Packard Scintillator
299; Canberra Packard, Berks, England) was added, and the amount of
radioactivity was counted (Pakard Tri-Carb 4000 liquid scintillation counter).
Statistical analysis.
All data are presented as means ± standard errors of the mean (SEM). Analysis was performed by using
the Mann-Whitney U test and calculated by the computer multifunction
statistics library package NWAStatpak (Northwest Analytical Inc.,
Portland, Oreg.).
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RESULTS |
Because both LPS and TNF- treatments of neutrophils are known
to result in the priming of the NADPH oxidase and the activation of MAP
kinases, we directly measured the relative levels of these two agents
in the six dialysis fluids employed in this study. TNF- levels were
below that detectable by ELISA; furthermore, the molecular weight of
the priming agent in PDE is considerably lower than that of the
cytokine (6). Endotoxin levels in PDE were 71.25 ± 9.22 pg ml1 (mean ± SEM) (range 57 to 114 pg
ml1); again, these levels are below those reported to
prime neutrophils (35). Furthermore, LPS priming requires
preincubation of neutrophils with endotoxin while PDE priming is
immediate (6, 35). Further, biochemical analysis of the
fluids employed revealed protein levels (mean ± SEM) of 3.18 ± 0.37 mg ml1 (range 2.25 to 4.90 mg ml1),
urea concentrations of 18.18 ± 1.56 mM (range 14.0 to 25.4 mM),
and creatinine concentrations of 900 ± 70 µM (range 707 to 1290 µM). As for TNF-, the levels of interleukin 1 were below that
detectable by ELISA.
Effects of inhibition of MAP kinases and protein tyrosine kinase
upon NADPH oxidase activity.
Figure
1 shows the effects of treating
neutrophils with PD-098,059, a potent and specific inhibitor of MAP
kinase kinase (MEK) which is reported to catalyze the phosphorylation
of erkI/II upon threonine202 and
tyrosine204. PD-098,059 was a poor inhibitor of
fMLP-induced superoxide generation in human neutrophils. Preincubation
of cells for 30 min with the compound gave an estimated 50% inhibitory
concentration (IC50) of ca. 50 µM for both PDE-primed and
unprimed cells. This inhibitory concentration did not affect cell
viability, as determined by measurement of ATP release (Fig. 1), and
did not affect superoxide measurement in a cell-free xanthine-xanthine
oxidase system (data not shown), demonstrating that it did not act as a
free radical scavenger. The effect of SB203580
[4-(4-fluorophenyl)-2-(4-methylsulfinylphenyl)-5-(4-pyridyl)1H-imidazole], a p38 kinase inhibitor, upon fMLP-induced superoxide release from PDE-primed and nonprimed neutrophils is shown in Fig.
2. SB203580 was a moderately good
inhibitor of fMLP superoxide anion generation, displaying an estimated
IC50 of 1.5 µM. When neutrophils were primed with PDE,
the concentration response curve of the inhibitor was significantly
left-shifted, reducing the effective IC50 by sixfold to
0.25 µM. In a similar manner to PD-098,059, the effectiveness of
SB203580 at inhibiting NADPH oxidase activity increased with increasing
incubation times (up to 60 min) (data not shown). However, significant
inhibition was evident when oxidase activity was measured immediately
after the addition of the inhibitor (i.e., no incubation period) (data
not shown). In our hands, an incubation period of 30 min prior to
stimulation by fMLP produced consistent results for both SB203580 and
PD-098,059. Figure 3 demonstrates typical results from an individual representative experiment showing that when
the concentration of SB203580 was >1.5 µM, the priming effect of PDE
to fMLP was completely lost. However, for both primed and unprimed
neutrophils the generation of superoxide in the presence of SB203580
could not be completely abolished, even at concentrations approaching
100 µM, suggesting that the inhibitor has little effect upon
spontaneous, unstimulated superoxide generation. Further experiments
were conducted with the recently developed pyridinyl imidazole
inhibitor SB203590
[4-(4-fluorophenyl)-2-(4-hydroxyphenyl)-5-(4-pyridyl)1H-imidazole], a compound that is reportedly more selective for the isoform of p38
(p38) (13). These experiments demonstrated that SB203590, like SB203580, was a highly potent inhibitor of the priming response of
PDE (IC50 = 1 µM and 0.2 µM for unprimed and
primed neutrophils, respectively) (Fig.
4).
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FIG. 1.
The effect of PD-098,059 (0 to 100 µM) upon superoxide
generation in neutrophils challenged with fMLP (1 µM). Neutrophils
were incubated in buffer (open circles) or PDE (closed circles).
Results are expressed as percent inhibition from the control (no
PD-098,059) ± SEM (n = 6; six dialysis effluents
upon six donor neutrophils). Absolute control values (100%) were
1,777 ± 42 and 948 ± 52 relative light units (RLU) for
primed and unprimed cells, respectively. The inset shows the effect of
PD-098,059 (0 to 100 µM) upon ATP release from neutrophils (open
squares) and from ATP standard control (closed squares).
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FIG. 2.
The effect of SB203580 (0 to 3 µM) upon superoxide
generation in neutrophils challenged with fMLP (1 µM). Neutrophils
were incubated in buffer (open circles) or PDE (closed circles).
Results are expressed as percent inhibition from the control (no
SB203580) ± SEM (n = 6; six dialysis effluents
upon six donor neutrophils). Absolute control values (100%) were
2,029 ± 232 and 1,001 ± 108 relative light units (RLU) for
primed and unprimed cells, respectively. Asterisks indicate
P values of  0.05 (Mann-Whitney U test) with respect to the
primed counterpart. The inset shows the effect of SB203580 (0 to 100 µM) upon ATP release from neutrophils (open squares) and from ATP
standard control (closed squares).
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FIG. 3.
A representative experiment showing the effect of
SB203580 (0 to 25 µM) upon superoxide generation in neutrophils
challenged with fMLP (1 µM). Neutrophils were incubated in buffer
(open circles) or PDE (closed circles) during stimulation. The results
are expressed as mean relative light units (RLU) ± SEM (three
donor neutrophils upon three separate dialysis effluents).
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FIG. 4.
The effect of SB203590 (0 to 3 µM) upon superoxide
generation in neutrophils challenged with fMLP (1 µM). Neutrophils
were incubated in buffer (open circles) or PDE (closed circles).
Results are expressed as percent inhibition from the control (no
SB203590) ± SEM (n = 6; six dialysis effluents
upon six donor neutrophils). Absolute control values (100%) were
2,427 ± 202 and 1,391 ± 98 relative light units (RLU) for
primed and unprimed cells, respectively. Asterisks indicate
P values of 0.05 (Mann-Whitney U test) with respect to the
primed counterpart.
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In view of the results obtained with specific inhibitors of MAP kinase
pathways, we also treated neutrophils with the broad-range
tyrosine
kinase inhibitor genistein (Fig.
5).
Incubation of neutrophils
with 10 µM genistein resulted in a >80%
inhibition of fMLP-stimulated
superoxide generation. We estimated the
IC
50 of this compound
in our system to be 1 µM. Priming
of neutrophils by PDE after
treatment with genistein did not effect the
potency of the inhibitor.
As with the MAP kinase inhibitors PD-098,059
and SB203580, the
observed loss of oxidase activity was not
attributable to cell
death, since incubation of neutrophils with
concentrations of
genistein up to 100 µM did not effect the release
of ATP (Fig.
5). Furthermore, genistein did not effect the measurement
of superoxide
generated by a cell-free system (data not shown).
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FIG. 5.
The effect of genistein (0 to 10 µM) upon superoxide
generation in neutrophils challenged with fMLP (1 µM). Neutrophils
were incubated in buffer (open circles) or PDE (closed circles).
Results are expressed as percent inhibition from the control (no
genistein) ± SEM (n = 6; six dialysis effluents
upon six donor neutrophils). Absolute control values (100%) were
2,942 ± 302 and 1,461 ± 185 relative light units (RLU) for
primed and unprimed cells, respectively. The inset shows the effect of
genistein (0 to 100 µM) upon ATP release from neutrophils (open
squares) and from ATP standard control (closed squares).
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Phosphorylation of erkI/II and p38.
In an attempt
to confirm that p38 and not erkI/II was the MAP kinase
signalling pathway utilized by PDE in its priming of human neutrophil
NADPH oxidase activity, we examined the phosphorylation status of these
proteins in neutrophils exposed to PDE. Both p38 and erkI/II
require phosphorylation upon threonine and tyrosine residues to become
fully functional enzymes (28). This change in
phosphorylation status can be detected either by the use of antibodies
specific for the phosphorylated enzyme or by a mobility shift of the
protein on polyacrylamide gels (i.e., the phosphorylated form of the
protein migrates more slowly).
Figure
6 shows the effect of exposure of
neutrophils to PDE for various time periods. Western blots were probed
with a polyclonal
antibody to
erkII (p42), the predominant
erk form found in human
neutrophils (
22). The
antibody demonstrated slight cross-reactivity
with
erkI (as
indicated by the suppliers and as shown in Fig.
6A, lanes 3 to 7);
however, no mobility shift of the protein was
observed (lanes 1 to 7),
suggesting that phosphorylation had not
occurred. As a positive control
for this experiment, some cells
were stimulated with 100 ng of PMA
ml
1 (Fig.
6A, lane 8), a known activator of
erk (
38). In these
cells, the
erkII
band appeared as a doublet, with the slower-migrating
band representing
the phosphorylated protein. These results were
further confirmed by
stripping the blot and reprobing it with
an antibody specific for
phosphorylated
erkI/II. In this case,
only the PMA-treated
samples showed a positive band (Fig.
6B,
lane 8).
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FIG. 6.
The effect of PDE upon the phosphorylation of
erkII (p42) in the cytosol of human neutrophils. Neutrophils
were treated with buffer or PDE for the times indicated (lanes 1 to 7).
(A) Cellular proteins were separated as described in Materials and
Methods and probed with a polyclonal antibody to total
erkII. (B) After visualization, the blot was stripped and
reprobed with a polyclonal antibody specific for the phosphorylated
form of erkII. Lanes 8 show a positive control, i.e., cells
stimulated with 100 ng of PMA ml1. The positions of
erkII, phosphorylated erkII (P-erkII),
and erkI are indicated by the appropriate arrows.
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Figure
7A shows the effect of probing the
same blot with an antibody to p38. The results indicate that all of the
sample lanes
contained a similar total amount of this protein. Further
reprobing
of this blot with an antibody specific for the phosphorylated
protein (Fig.
7B) reveals that not only PMA stimulation of cells
results in p38 phosphorylation (lane 8) but also exposure of cells
to
PDE. Phosphorylation by PDE was transient, appearing after
30 s
(Fig.
7b, lane 3), peaking at 60 s (lane 5), and diminishing
by 5 min (lane 7). Some phosphorylation of p38 was observed in
cells in
buffer; this phosphorylation appeared to increase with
time (Fig.
7b,
lanes 2, 4, and 6), suggesting that some activation
of neutrophils had
occurred during sample handling. The majority
of both
erkII
and p38 was present in the cytosolic fraction of
sonicated neutrophils.
Furthermore, we were able to detect only
the phosphorylated form in
this fraction (data not shown).
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FIG. 7.
The effect of PDE upon the phosphorylation of p38 in the
cytosol of human neutrophils. Neutrophils were treated with buffer or
PDE for the times indicated (lanes 1 to 7). (A) Cellular proteins were
separated as described in Materials and Methods and probed with a
polyclonal antibody to total p38. (B) After visualization, the blot was
stripped and reprobed with a polyclonal antibody specific for the
phosphorylated form of p38 (P-p38). Lanes 8 show a positive control,
i.e., cells stimulated with 100 ng of PMA ml1.
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Phosphorylation and translocation of cPLA2.
One
mechanism by which p38 activation may result in a primed oxidase
response is through the phosphorylation and/or membrane translocation
of cPLA2. We therefore investigated the activation and
translocation of this enzyme in neutrophils exposed to PDE. Figure
8 demonstrates that exposure of
neutrophils to PDE for periods up to 5 min failed to phosphorylate
cPLA2, compared to PMA-treated cells (Fig. 8, lanes 8). The
majority of cPLA2 was present within the cytosolic
preparation of neutrophils (Fig. 8A); however, we were able to detect
small amounts of PLA2 in solubilized membrane preparations
(Fig. 8B), but exposure of neutrophils to PDE did not result in greater
translocation of the enzyme to the membrane.
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FIG. 8.
The effect of PDE upon the phosphorylation and
translocation of cPLA2 in human neutrophils. Neutrophils
were treated with buffer or PDE for the times indicated (lanes 1 to 7).
Cellular proteins were separated as described in Materials and Methods
and probed with a polyclonal antibody to cPLA2. Blots show
the presence of cPLA2 in cytosolic fractions (A) and
membrane fractions (B). Lanes 8 shows a positive control, i.e., cells
stimulated with 100 ng of PMA ml1. The positions of
cPLA2 and phosphorylated cPLA2
(P-cPLA2) are indicated by the appropriate arrows.
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To confirm that the PDE-induced activation of p38 did not give rise to
the subsequent activation of cPLA
2, we directly measured
the activity of this enzyme in both cytosol and membrane preparations
of human neutrophils exposed to PDE by using
14C-labelled
phosphatidylcholine as the substrate. The results shown
in Table
1 demonstrate that the exposure of
neutrophils to PDE
for periods of up to 5 min failed to induce a
measurable increase
in cPLA
2 activity in cytosolic
neutrophil fractions. We were unable
to access the activation of the
enzyme in membrane preparations
under these conditions, possibly
because of a dilution of labelled
substrate by membrane phospholipids
(data not shown).
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DISCUSSION |
CAPD is a popular form of treatment for patients with end-stage
renal failure that is frequently complicated by episodes of recurrent
bacterial peritonitis. Peritonitis is characterized by an influx of
neutrophils into the peritoneal cavity; however, despite this vigorous
response these cells appear unable to function normally. We have
previously reported that PDE removed from end-stage renal failure
patients following a 4-h intraperitoneal dwell contains a potent
priming agent of both fMLP-stimulated arachidonic acid release
(17) and NADPH oxidase activity (6) in human
neutrophils. We have speculated that the excessive release of
neutrophil reactive oxygen species due to this priming agent may scar
the peritoneal membrane, compromising its efficiency during dialysis
and promoting peritonitis (17). In this study, we have
investigated the MAP kinase signalling pathway(s) utilized by PDE and
investigated the possibility that MAP kinase activation results in
cPLA2 phosphorylation, causing release of arachidonic acid
and superoxide anion.
To initially investigate the relationship between the priming of human
neutrophils and oxidase activity, we studied the effects of two
recently developed specific inhibitors of the erk and p38 MAP kinase pathways upon fMLP-induced superoxide release (PD-098,059 and SB203580, respectively). In agreement with other authors, we
established that the selective inhibition of MAP kinase kinase (MEK) by
PD-098,059 has little effect upon fMLP-stimulated oxidase activity
(29, 37, 38). Our data would suggest that erk
plays only a very limited role in mediating the oxidase response in human neutrophils. This observation is further supported by the fact
that the fMLP-induced gel shift of erkII (indicative of
phosphorylation) (38) is completely abolished by 30 µM
PD-098,059, while the same inhibitory concentration will reduce only
the oxidase response by 20% (29, 38). Avdi et al.
(1) have reported inhibition of the fMLP response
approaching 45% with 10 µM PD-098,059; however, the conditions of
their assays differed from ours in that they employed a 60-min
incubation period with the inhibitor and they pretreated neutrophils
with the fungal metabolite and priming agent cytoclaisin B.
In contrast to PD-098,059, treatment of human neutrophils with either
SB203580 or SB203590 markedly reduced fMLP-induced oxidase activity.
Both of these pyridinyl imidazole inhibitors are thought to inhibit p38
kinase activity by binding to the ATP binding site (36).
However, tyrosine phosphorylation of p38 appears not to be effected by
this compound since TNF--induced phosphorylation of p38 is
unaffected by the inhibitor, but the activity of the p38 kinase is
markedly reduced at about 15 µM (34). In our hands, we
report an IC50 for SB203580 of approximately 1.5 µM,
which is in good agreement with other authors who have used similar imidazole compounds (e.g., Schnyder et al. report an IC50
of approximately 2 µM for Smith Kline and French compound 86002 [29] while Nick et al. report a value of between 0.5 and 1.0 µM for the same compound [25]).
Interestingly, when neutrophils were primed with PDE the concentration
response curve to SB203580 was significantly left-shifted, reducing the
IC50 to approximately 0.25 µM. Indeed, concentrations of
SB203580 that exceeded 1.5 µM completely destroyed the ability of PDE
to prime cells for fMLP-induced oxidase activity. These data would
strongly suggest that the priming effect of PDE on human neutrophils is
mediated via the p38 kinase. It is well documented that the
tyrosine-directed phosphorylation of proteins is an essential
prerequisite for activation of the NADPH oxidase, particularly during
the early phase of superoxide anion release (18). Since both
erk and p38 require phosphorylation
(threonine202/tyrosine182 and
threoninine180/tyrosine182, respectively) for
their complete activation, it would seem reasonable to assume that both
of these enzymes would act as potential targets for genistein, a potent
inhibitor of tyrosine specific kinases. This, however, does not appear
to be the case. GM-CSF-enhanced erk activity and the
subsequent phosphorylation of cPLA2 are both blocked by
genistein in a time- and concentration-dependent manner (11,
23). Yet the compound is ineffective at preventing
cPLA2 phosphorylation by agents that signal via the p38
kinase pathway, i.e., TNF- and LPS (10, 33). In agreement
with others (27, 29, 38), we found that genistein was a good
inhibitor of fMLP-induced superoxide release. However, it was equally
as effective against PDE-primed neutrophils, suggesting that the agent
inhibits tyrosine kinases that are essential for oxidase activity but
are also common to both the p38 and erk pathways.
To further confirm the involvement of the p38 kinase in the priming of
human neutrophils by PDE, we directly examined the phosphorylation of
MAP kinases in cell lysates. In agreement with other authors (2,
31), we found that the majority of both erk and p38
proteins resided in the cytosolic fraction of neutrophils. Furthermore,
by using phospho-specific antibodies and electrophoretic mobility
shifts, we were able to clearly establish that only p38 was
phosphorylated in the presence of PDE. The phosphorylation of this
protein was transient, with maximal phosphorylation being apparent
after 60 s of exposure to effluent.
Although over the past several years it has become apparent that both
direct stimuli, such as fMLP, PMA, and platelet-activating factor
(1, 15, 25, 29, 30, 38), and priming agents, such as GM-CSF,
LPS, and TNF- (10, 24, 32, 33, 37), result in the
activation of MAP kinase cascades in human neutrophils, the pathway
from these cascades to physiological responses has yet to be
determined. Several substrates of both erk and p38 have recently been identified (21). One such substrate that has
generated recent interest is the 85-kDa cPLA2
(16). In human neutrophils, cPLA2 is thought to
translocate from the cytosol to the membrane as intracellular
Ca2+ concentrations rise. This translocation, coupled with
phosphorylation upon serine505 results in a fully activated
enzyme. Once at the membrane, cPLA2 selectively cleaves
arachidonyl-containing phospholipids resulting in the liberation of
arachidonic acid and a lyso-phospholipid (9).
Since arachidonic acid is a potent activator and primer of human
neutrophil oxidase activity (5, 12, 17, 27) and since
exposure of neutrophils to PDE results in the release of the fatty acid
(17), it is tempting to speculate that cPLA2 is
the substrate for PDE-activated p38. However, we were unable to
demonstrate either increased phosphorylation or translocation of this
enzyme upon exposure of neutrophils to PDE.
Although the target of PDE-activated p38 remains elusive, several
possibilities are apparent. The NADPH oxidase in human neutrophils is a
multicomponent enzyme that is functional only when a number of
cytosolic and granule components combine at the membrane. One important
cytosolic component of this enzyme complex is
p47phox. For activation, this protein requires
phosphorylation upon a number of serine residues, several of which are
recognized by proline-directed kinases, such as erk and p38
(2). Furthermore, the locations of both activated p38 and
p47phox, i.e., the cytoplasm, are consistent
with the latter being a potential substrate for p38.
Another important component of the neutrophil NADPH oxidase is the
terminal electron donor b558. This flavohemoprotein is believed to be located within the specific granules of neutrophils (26). The observation that imidazole inhibitors, such as
SB203580 (rather than MEK inhibitors, such as PD-098,059), inhibit the expression of the neutrophil adhesion molecule CD18/11b, also located
within the specific granules (29), is a clear indication that p38 is involved in the control of the release of these granules. We have previously demonstrated that PDE augments specific granule release in neutrophils (8). The observation that this
release precedes oxidase activity (8) and mimics the time
coarse of p38 activation by PDE, i.e., peaks at approximately 1 min,
would suggest that control of degranulation resulting in enhanced
release of b558 and hence oxidase activity is a more likely
route for PDE priming. If this is the case, arachidonic acid release
seen in PDE-treated neutrophils may be secondary to oxidase activity and arise as a result of release of the 14-kDa secretory
PLA2, also located within the specific granules
(20). Until effective and specific cytosolic and secretory
PLA2 inhibitors are developed, the contribution of these
two enzymes to oxidase activity remains difficult to determine
(5).
In summary, our studies suggest that priming of human neutrophils with
PDE, in a manner similar to that of LPS and TNF-, is via the p38
kinase and not erk. However, unlike these conventional priming agents, we were unable to show that activation of this cascade
resulted in phosphorylation or activation of cPLA2. The possibility remains that p38 activation by PDE may result in direct phosphorylation of oxidase components or may simply increase release of
secondary granules to potentiate superoxide release. These possibilities are currently under investigation in our laboratory.
| |
ACKNOWLEDGMENTS |
This work was supported by a grant from the Trent Region Research
Scheme, Sheffield, United Kingdom.
We thank Michael Seeds of Wake Forest University, Winston-Salem, North
Carolina, for his useful advise concerning cPLA2 assays. We
also thank Trent Regional Health Authority, Sheffield, United Kingdom,
and Baxters Healthcare Corp., Deerfield, Ill., for their support.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Medical Research
Centre, City Hospital, Hucknall Road, Nottingham, NG5 1PB. United Kingdom. Phone: (0115) 9627650, ext. 46509. Fax: (0115) 9602140. E-mail: iandaniels25{at}hotmail.com.
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Clinical and Diagnostic Laboratory Immunology, November 1999, p. 878-884, Vol. 6, No. 6
1071-412X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
