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Journal of Virology, July 2001, p. 6450-6459, Vol. 75, No. 14
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.14.6450-6459.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Adenovirus Type 7 Induces Interleukin-8 Production
via Activation of Extracellular Regulated Kinase 1/2
M. J.
Alcorn,1,2
J. L.
Booth,3
K. M.
Coggeshall,1,2 and
J. P.
Metcalf1,3,*
Pulmonary and Critical Care Division of the
Department of Medicine3 and Department
of Microbiology and Immunology,1 University of
Oklahoma Health Sciences Center, and Program in
Immunobiology and Cancer, Oklahoma Medical Research
Foundation,2 Oklahoma City, Oklahoma
Received 16 January 2001/Accepted 13 April 2001
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ABSTRACT |
Infection with adenovirus serotype 7 (Ad7) frequently causes lower
respiratory pneumonia and is associated with severe lung inflammation
and neutrophil infiltration. Earlier studies indicated release of
proinflammatory cytokines, specifically interleukin-8 (IL-8), by
pulmonary epithelial cells following infection by Ad7. However, the
mechanism of IL-8 induction by Ad7 is unclear. We have explored the
role of the Ras/Raf/MEK/Erk pathway in the Ad7-associated induction of
IL-8 using a model system of A549 epithelial cells. We found that Ad7
infection induced a rapid activation of epithelial cell-derived Erk.
The MEK-specific inhibitors PD98059 and U0126 blocked Erk activation
and release of IL-8 following infection with Ad7. Treatment with
PD98059 is cytostatic and not cytotoxic, as treated cells regain the
ability to phosphorylate Erk and secrete IL-8 after removal of the
drug. The expression of a mutated form of Ras in A549 epithelial cells
blocked the induction of IL-8 promoter activity, and MEK inhibitor
blocked induction of IL-8 mRNA. These results suggest that the
Ras/Raf/MEK/Erk pathway is necessary for the Ad7 induction of IL-8 and
that induction occurs at the level of transcription. Further, the
kinetics of Erk activation and IL-8 induction suggest that an early
viral event, such as receptor binding, may be responsible for the
observed inflammatory response.
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INTRODUCTION |
Adenovirus (Ad) infections cause
pneumonia and disseminated disease in both immunocompromised and
nonimmunocompromised hosts. There are at least 49 types of Ad, as
defined by serological methods. While many of the Ad serotypes cause
infectious syndromes, most are mild upper respiratory infections. In
contrast, Ad type 7 (Ad7) has been implicated as a cause of a more
severe lower respiratory tract infection. Ad7 has been isolated during
episodes of pneumonia in military recruits and children
(15). Diffuse alveolar damage similar to that seen in
acute respiratory distress syndrome is often a consequence of Ad7
infection and can lead to permanent damage to lung tissue as a result
of the massive inflammation (39).
Ad-based vectors have been employed for in vitro and in vivo delivery
of genes into mammalian cells. Most vectors used in gene therapy are
derived from the Ad5 serotype. However, the use of Ad5-based vectors in
nonhuman primates was associated with a profound inflammatory response
(41). While it may be a potential delivery vector, Ad7 is
not currently being used as a human gene therapy vector. Ad7 employs a
unique but unknown cellular receptor for viral fiber protein. However,
this feature may make Ad7 a potential route to alleviate the limited
tissue tropism of existing Ad vectors. Thus, a better understanding of
Ad-triggered inflammation is important to alleviate the symptoms of
wild-type Ad infection and to reduce the potential side effects of Ad
gene therapy vector administration.
Alveolar epithelial cells, which are infected during acute Ad
infection, are likely mediators of the inflammatory response to Ad
(1). The CXC chemokine interleukin-8 (IL-8) is an
important mediator of the inflammatory response to many stimuli,
including viruses (5). Additionally, IL-8 may be important
in the pathophysiology of asthma and obstructive lung disease, since
IL-8 levels are increased in patients with these chronic inflammatory
disorders (35). IL-8 has also been measured in
bronchoalveolar lavage fluid from patients with acute respiratory
distress syndrome (25) and secretions from patients with
Ad19-associated keratitis (12). Most importantly, IL-8 is
also a major neutrophil chemoattractant and activator (reviewed in
reference 5). Neutrophils are prominent in lavage fluid in
many animal models of Ad infection, as well as upon exposure of humans
and nonhuman primates to genetically modified Ad5 vectors known to
induce IL-8 in vitro (6, 10, 20, 21, 41).
Our earlier studies showed that human pulmonary epithelial-like cells
release IL-8 upon infection with Ad7 (7); however, the
mechanism of IL-8 induction is not understood. Other studies of
infectious processes caused by agents including respiratory syncytial
virus, lipopolysaccharide, mycobacterium, and Pseudomonas pyocyanin have indicated a role for the cellular kinase extracellular regulated kinase (Erk) in the induction of IL-8 by host cells (11, 13, 31). Erk activation is initiated by a wide
variety of growth factor receptors through a specific set of signal
transduction events. These events culminate in the receptor recruitment
of a guanine nucleotide exchange factor into proximity with plasma membrane-localized Ras to catalyze Ras activation by GTP binding (reviewed in reference 38). Once activated, Ras-GTP
initiates a cascade of serine-threonine kinases, beginning with Raf,
which phosphorylates and activates mitogen-activated protein kinase (MAPK)-activating kinase (MEK). MEK phosphorylates and activates Erk,
which translocates to the nucleus to activate transcription factors,
such as NF-
B and AP-1. Both of these transcription factors are
important for the induction of IL-8 transcription (reviewed in
reference 5). Induction of IL-8 does not exclusively
involve signaling through activation of the Erk pathway. For example, PD98059 (the inhibitor of Erk used in our study) does not block tumor
necrosis factor (TNF)- and IL-1-stimulated IL-8 production from
pulmonary vascular endothelial cells (23) or
TNF-stimulated IL-8 production from neutrophils (42).
Likewise, PD98059 had a minimal effect on group B streptoccoccal
induction of IL-8 in these cells (2).
Earlier experiments using an epithelial cell model and infection with
an Ad5-based gene therapy vector demonstrated activation of the Erk
pathway soon after infection and of IL-8 production at later time
points. However, the relationship between Erk induction and IL-8
production is not understood (10). Our laboratory has previously demonstrated that the production of IL-8 by host cells following Ad7 infection occurs more rapidly than that induced by
Ad5-based gene therapy vectors, i.e., within 2 rather than 24 h
(7). We hypothesized that the difference in the kinetics of IL-8 production might be due to differences in signal transduction pathways initiated by Ad7. Therefore, we sought to address the role of
the Erk pathway in Ad7-associated induction of IL-8.
In this report, we demonstrate that activation of the Ras/Raf/MEK/Erk
pathway correlates with induction of IL-8 by Ad7. Using two specific
inhibitors of the Erk pathway, we show that Erk activation is essential
for IL-8 production stimulated by Ad7. Inhibition of the Erk pathway
and IL-8 production by these inhibitors can be reversed and therefore
is not due to a nonspecific cytotoxic effect. Additionally, we observed
that cellular expression of a dominant-negative Ras molecule blocks the
ability of the cells to induce IL-8 promoter activity upon Ad7
infection and that chemical inhibition of Erk blocks IL-8 mRNA
induction by virus. We conclude that Ad7-mediated activation of the Erk
pathway is causally related to the subsequent production of IL-8, which
can contribute to inflammatory disease in the host.
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MATERIALS AND METHODS |
Cells and viruses.
The human pulmonary epithelial cell line
A549 was used for these studies. This cell line, derived from a patient
with lung carcinoma, has characteristics of alveolar type II cells and
was obtained from the American Type Culture Collection, Manassas, Va.
(ATCC CCL-185) (30). The cells were maintained in
Dulbecco's modified Eagle's medium (DMEM) with 2 mM
L-glutamine and 80 µg of gentamicin/ml plus 10% fetal
bovine serum (FBS) at 37°C in a humidified incubator at 5%
CO2. Ad7 was obtained from the American Type Culture
Collection (ATCC VR-7). Virus was propagated as described previously
(7). Infected A549 cells were incubated for 3 to 4 days in
DMEM plus 10% FBS; virus was harvested by three freeze-thaw cycles and
purified by ultracentrifugation in CsCl gradients as described
previously (24). The purified virus preparation was dialyzed extensively against phosphate-buffered saline (PBS), pH 7.2, plus 10% glycerol, titered by a cytotoxic plaque assay (27), and stored at 
80°C.
Kinase assays, immunoprecipitation, SDS-PAGE, and
immunoblotting.
A549 cells grown on 10-cm-diameter dishes for
18 h in serum-free DMEM to approximately 90% confluency were
infected with Ad7 at a multiplicity of infection (MOI) of 50 in 3 ml of
DMEM minus FBS and incubated at 37°C and 5% CO2 for
various times. Phorbol 12-myristate 13-acetate (PMA; Sigma) at 100 ng/ml (unless otherwise stated) was used as a positive control, and
mock-infected negative control cells were exposed to equivalent volumes
of virus-free buffer (PBS plus 10% glycerol). When appropriate, the
mock-infected cells were also treated with inhibitor solvent (dimethyl
sulfoxide [DMSO]). Cells treated with various concentrations of the
specific MEK inhibitor PD98059 (Calbiochem) (3, 16) were
incubated for 30 min at 37°C and 5% CO2 in 1 ml of
serum-free DMEM prior to the addition of Ad7 or PMA. Where indicated,
PD98059 was washed out of the cells by three successive washes in PBS.
Negative control cells were preincubated with equivalent amounts of
DMSO. After infection, A549 cells were washed three times in ice-cold
PBS and lysed in cold lysis buffer (150 mM NaCl; 50 mM Tris [pH 8.0] 10 mM [each] EDTA, NaF, and NaP~P; 1% NP-40; 0.5% Na
deoxycholate; 0.1% sodium dodecyl sulfate [SDS]; 3 mM sodium
vanadate; 10 µg of aprotinin and leupeptin/ml). The cells were
scraped from the tissue culture dishes, and the lysates were
transferred to Eppendorf tubes. Postnuclear lysates were
immunoprecipitated overnight at 4°C with 3 µg of rabbit anti-Erk1/2
antibody (Upstate Biotechnology, Inc., Lake Placid, N.Y.), followed by
incubation with 25 µl of Sepharose-bound fusion protein A/G (Pierce
Inc., Rockford, Ill.) for 1 h at 4°C. Control lysates were
comparably immunoprecipitated with an equivalent amount of normal
rabbit immunoglobulin (NRIg) after PMA stimulation. The
immunoprecipitated material was washed five times with lysis buffer
containing 1 mM sodium vanadate, resuspended in 50 µl of SDS sample
buffer (60 mM Tris [pH 6.8], 10% glycerol, 2.3% SDS), and heated to
95°C for 5 min. The samples were separated by SDS-12.5%
polyacrylamide gel electrophoresis (PAGE) and electrophoretically
transferred to nitrocellulose membranes. To detect activated
phosphorylated Erk (22, 36), the filters were
immunoblotted with a mouse monoclonal antibody specific for both the
p44 and p42 diphosphorylated forms of Erk (Upstate Biotechnology, Inc.). The filters were developed with horseradish peroxidase-labeled goat anti-mouse IgG (Kirkegaard and Perry Laboratories). The same filter was stripped with 2% SDS in 50 mM Tris, pH 6.0, to remove the
primary antibody and subsequently reprobed with polyclonal anti-Erk1/2
antibody (Upstate Biotechnology, Inc.) that recognizes both
phosphorylated and nonphosphorylated Erk. Blots were developed and
quantified using the LumiImager F1 system and LumiAnalyst software
(Boehringer Mannheim GmbH, Mannheim, Germany).
In vitro kinase assay.
The protocol to immunoprecipitate Erk
was identical to that described above. Immunoprecipitated Erk was
resuspended in 10 µl of kinase assay dilution buffer (25 mM HEPES
[pH 7.0], 0.15 M NaCl, 10 mM MnCl2, 1 mM
NaVO4, 5 mM dithiothreitol, 0.5% NP-40). A reaction buffer
composed of 75 mM MgCl2, 500 µM ATP, 10 mCi [32
-P]ATP, and 2 mg of myelin basic protein (MBP)/ml
was added to the bead-bound Erk (20 µl/reaction) and incubated for 15 min at 30°C. The reaction was stopped by adding 5× SDS sample buffer and incubating the mixture at 95°C for 5 min. The material in the
kinase reaction was separated by SDS-15% PAGE and transferred to a
nitrocellulose membrane before being sealed and exposed to a
PhosphorImager screen. The bands representing phosphorylated MBP were
analyzed using Imagequant software after being scanned on a Storm
PhosphorImager (Molecular Dynamics).
IL-8 ELISA.
After overnight growth at 37°C and 5%
CO2 on 12-well plates in DMEM plus 10% FBS, 8.5 × 105 A549 cells/well were infected with Ad7 at an MOI of 50 in 0.3 ml of DMEM plus 0.5% FBS and incubated for 1 h at 37°C
and 5% CO2. Subsequently, 0.7 ml of DMEM plus 10% FBS was
added to each well, and the plates were returned to the incubator. PMA
(100 ng/ml) served as a positive control, PBS plus 10% glycerol was used as a negative control, and all controls were treated similarly to
Ad-infected cells. Cells exposed to various concentrations of PD98059
or U0126 (Calbiochem) were incubated for 1 h in DMEM plus 0.5%
FBS prior to the addition of Ad7 or PMA. The final concentration of
PD98059 or U0126 was maintained throughout the experiment. For
specified experiments, the PD98059 was washed out by three successive
washes in PBS. Negative control cells were treated with DMSO. At
various times, the culture supernatants were collected and analyzed for
IL-8 protein by a sandwich ELISA (R&D Systems, Minneapolis, Minn.).
Transfections.
A549 cells were seeded in 25-cm2
flasks at 105 cells per flask and grown overnight. The
cells were transfected with 1 µg of the 162 to +44 IL-8 lucerifase
reporter plasmid containing the IL-8 5' promoter region linked to a
luciferase reporter gene (a gift of Allen Brasier, University of Texas
Medical Branch, Galveston) (19). The transfections were
carried out with GenePorter 2 reagent (Gene Therapy Systems, San Diego,
Calif.). Where indicated the cells were cotransfected with 5 µg of
inactivated Ras (N17Ras [26]). After a 24-h incubation
period, the transfected cells were washed to remove the transfection
reagent, and fresh DMEM plus 10% FBS was added. After an additional
24-h incubation, the medium was replaced with serum-free DMEM. After 16 h of serum starvation, the transfected cells were treated with the MEK
inhibitor U0126 (25 µM) or DMSO and stimulated with Ad7 (MOI = 50) or PMA. The cells were incubated for 6 h before lysis. Postnuclear
lysates were assessed for induced luciferase activity with an assay kit from Promega (Madison, Wis.).
Isolation of RNA and Northern blot analysis.
Cells were
infected as described above prior to harvest in the presence or absence
of 25 µM PD98059. All solutions used for RNA preparation were treated
with diethyl pyrocarbonate at 1:1,000. The cells were scraped off the
plates, pelleted by centrifugation, and washed with PBS. Whole cellular
RNA was prepared using Trizol reagent (Gibco BRL, Grand Island, N.Y.).
The RNA was measured by UV absorbance at 260 nm and stored at 70°C
prior to Northern analysis. RNA was dissolved in a MOPS
(morpholinepropanesulfonic acid)-formaldehyde-formamide solution and
heated for 5 min at 60°C. Samples (5 µg/lane) were run on an
agarose-formaldehyde (1.5% agarose-2.2 M formaldehyde-(MOPS) gel.
The gel was stained with ethidium bromide.
Following overnight capillary transfer to a Gene Screen (Dupont, NEN,
Boston, Mass.) membrane, the RNA was probed with a 32P
end-labeled 30-bp oligomer complementary to the IL-8 protein coding
region (7). Fresh buffer was added to the blot along with
the amount of probe required to give 106 counts/ml. Salmon
sperm DNA was added to block nonspecific binding. After incubation, the
blot was removed, washed, and exposed, and signals were quantitated
using a Storm PhosporImager.
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RESULTS |
Induction of IL-8 protein by Ad7.
We first investigated
the ability of A549 human lung epithelial cells to respond to Ad7
infection by the production of IL-8 protein. Confluent A549 cells were
either mock infected with viral diluent (PBS plus 10% glycerol),
infected with Ad7 (MOI = 50), or exposed to PMA (100 ng/ml).
Following various incubation times from 2 to 24 h, the
supernatants were harvested and assessed for IL-8 levels using a
sandwich ELISA. Ad7 infection of A549 cells caused a five- to eightfold
increase in IL-8 production above that of mock-infected cells (Fig.
1). Increased IL-8 was detectable within
2 h after infection with Ad7, reached maximal levels at 8 h, and
persisted but did not increase through 24 h. The amounts of IL-8
induced by Ad7 were 28 to 45% of the amounts induced by 100 ng of
PMA/ml and are similar to those seen in cells stimulated with TNF-
(7). These results confirm our previous model
(7) and establish that Ad7 induces the release of
proinflammatory IL-8 from A549 cells. The fold increase in IL-8
induction appears similar to that reported for respiratory syncytial
virus-infected A549 cells (4).
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FIG. 1.
Induction of IL-8 protein by Ad7. Confluent A549 cells
were exposed to wild-type Ad7 at an MOI of 50 or to virus-free buffer
(mock infection) for various times prior to measurement of supernatant
IL-8 by ELISA. PMA (100-ng/ml)-exposed cells were used as a positive
control. All measurements were performed in triplicate and are
expressed as the mean + standard error of the mean of three
separate experiments (see Materials and Methods).
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Infection with Ad7 rapidly induces Erk phosphorylation.
To
determine if Ad7-associated production of IL-8 correlated with Erk
activation, we first assessed Erk phosphorylation in confluent,
serum-starved A549 cells infected with Ad7 at an MOI of 50. At various
time intervals after infection, lysates of A549 cells were prepared and
total Erk1/2 was immunoprecipitated as described in Materials and
Methods. PMA stimulation served as a positive control for Erk
phosphorylation and was allowed to continue for a full 60 min.
Mock-infected lysates were prepared from cells at time zero and at 60 min. The immunoprecipitated Erk was analyzed by SDS-PAGE and by
immunoblotting with an antibody recognizing the dually phosphorylated
form of Erk (22, 36). The results (Fig. 2A and
B) revealed that Erk phosphorylation and
activation occurred within 5 min of Ad7 contact with the epithelial cells. Erk phosphorylation peaked at 10 min of exposure and returned to
background by 60 min. We quantitated Erk phosphorylation by determining
the ratio of phosphorylated Erk (Fig. 2A) to total Erk (Fig. 2B), and
the results are shown in Fig. 2C. The ratio corrects for variations in
the completeness of Erk immunoprecipitation. These results indicate
that Ad7 infection elicits Erk activation, which precedes IL-8
production in A549 epithelial cells.
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FIG. 2.
Kinetics of phosphorylation of Erk by Ad7. Serum-starved
A549 cells were exposed to Ad7 at an MOI of 50 for various times prior
to preparation of cellular lysates and Erk1/2 immunoprecipitation.
PMA-exposed cells (60 min), mock-infected cells (either time zero or 60 min), and cells exposed to PMA but immunoprecipitated with NRIg
(PMA-NRIg) were used as positive and negative controls. (A) Western
blot performed with antibody specific for dually phosphorylated Erk1/2.
(B) Same blot stripped and reprobed with pan-anti-Erk1/2 antibody. (C)
Activation of Erk as determined by ratio of phospho-Erk to total Erk
for each immunoprecipitate. In all cases, bands for both p44 and p42
Erks were included in the calculations. The data shown are
representative of three separate experiments.
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Inhibition of Ad induction of Erk by a chemical MEK inhibitor.
In mammalian cells, Erk is activated by a sequential pathway initiated
by GTP loading of Ras and is sustained by two additional kinases, Raf
and MEK (38). PD98059 was developed as a specific MEK
inhibitor (3, 16), which we utilized to determine the precise molecular relationship between Ad7-triggered Erk activation and
IL-8 production in the epithelial cell line. To determine if activation
of Erk by Ad7 occurred through the expected Raf/MEK pathway, we treated
A549 cells with increasing doses of PD98059 prior to a 20-min infection
with Ad7 or stimulation with PMA. Mock-infected cells were exposed to
an equal volume of virus-free buffer containing the same concentration
of inhibitor solvent (DMSO) as that used at the highest dose of
inhibitor. Figure 3A shows the
phosphorylation of Erk following stimulation or Ad7 infection in the
presence of increasing dosages of PD98059. Figure 3B shows the
same membrane reprobed for total Erk protein, and Fig. 3C shows the
ratio of the two. Ad7-inducible Erk phosphorylation was reduced in a
dose-dependent fashion by PD98059, and 25 µM PD98059 reduced Erk
phosphorylation in Ad7-exposed cells to near-background levels. These
amounts of PD98059 are consistent with earlier studies using the A549
cell line as a model to study Erk activation by epidermal growth factor
(9).
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FIG. 3.
Inhibition of Ad induction of Erk by MEK inhibitor.
Serum-starved A549 cells preincubated with various doses of the MEK
inhibitor PD98059 were exposed to Ad7 at an MOI of 50. PMA-stimulated
or mock-infected cells preincubated with or without PD98059 were used
as positive and negative controls. Cells exposed to PMA
immunoprecipitated with NRIg (PMA-NRIg) were used as a control for
immunoprecipitation. (A) Immunoblot of mock-infected, Ad7-infected, or
PMA-stimulated cell extracts probed with anti-phospho-Erk1/2 antibody.
(B) Same blot as in panel A stripped and reprobed with pan-anti-Erk1/2
antibody. (C) Ratio of pErk to Erk, determined as for Fig. 2. The data
are representative of four separate experiments.
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In our assay system, phosphorylation of Erk is used as an indicator of
activated Erk, capable of eliciting transcription factor
activation and
hence IL-8 production. In order to confirm that
Erk was indeed
enzymatically activated during Ad7 infections,
we performed in vitro
kinase assays on immunoprecitipated Erk.
As before, we prepared lysates
of A549 cells either mock infected,
Ad7 infected, or stimulated with
PMA. The proteins within the
in vitro kinase reactions were separated
by SDS-PAGE, and the
amount of
32P present in the MBP in
vitro kinase substrate was quantitated
by Storm image analysis. The
results (Fig.
4) showed that
mock-infected
cells displayed a low level of activated Erk, and this
activity
was further reduced by treatment with PD98059. Ad7 infection
of
A549 cells resulted in an ~20-fold increase in Erk enzymatic
activity
above that induced by mock infection. The induction by Ad7 of
Erk activity was reduced to near-background level in the presence
of
PD98059. PMA stimulation elicited increased Erk activity in
A549 cells,
and this stimulation was likewise susceptible to inhibition
by PD98059
treatment. These results indicate that analysis of
phosphorylated Erk
by immunoblotting with a phosphospecific antibody
is equivalent to
analysis of Erk enzymatic activity by in vitro
kinase measurements.
Additionally, these findings further establish
that PD98059 treatment
blocks Erk induction in A549 cells by PMA
or Ad7 infection.
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FIG. 4.
Ad7 induces Erk activity. A549 cells were mock infected,
PMA stimulated, or Ad7 infected (MOI = 50) in the presence or
absence of 25 µM PD98059 for 20 min prior to the preparation of
lysates. The lysates were immunoprecipitated overnight with anti-Erk1/2
antibody or with rabbit IgG NRIg. Immunoprecipitated Erk1/2 was then
analyzed for activity by an in vitro kinase assay as described in
Materials and Methods. (A) Phosphorylated MBP. (B) Plot of Storm
PhosphorImager units for each sample analyzed. +, present; ,
absent.
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Inhibition of Ad induction of IL-8 secretion by MEK inhibitor.
The findings described above demonstrate that Ad7-induced activation of
Erk is blocked by PD98059, an inhibitor of the kinase immediately
proximal to and essential for activation of Erk. We next sought to
discover whether activation of Erk was necessary for Ad7-associated
induction of IL-8 secretion. A549 cells were preincubated in media with
increasing doses of PD98059 (10, 25, and 50 µM) for 30 min prior to
stimulation. PD98059 remained in the media for the duration of the
experiments, and cells not treated with PD98059 were incubated in
medium containing an equivalent amount of inhibitor solvent (DMSO). The
cells were incubated for 8 h prior to harvesting of the supernatants
and analysis of secreted IL-8 levels by ELISA. Ad7 increased IL-8
production ninefold over that seen in mock-infected cells (Fig.
5A). Similar to the induction of Erk,
Ad7-stimulated IL-8 secretion was blocked in a dose-responsive manner
by PD98059. PD98059 similarly reduced IL-8 production by A549 cells
responding to PMA, a potent stimulant of Erk. Analysis of IL-8 levels
in 24-h supernatants (data not shown) demonstrated a comparable
dose-response relationship with PD98059 treatment.
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FIG. 5.
Inhibition of Ad induction of IL-8 protein by MEK
inhibitor. (A) Serum-starved A549 cells preincubated with increasing
doses of the MEK inhibitor PD98059 were exposed to Ad7 at an MOI of 50 or to virus-free buffer in medium plus 0.5% FBS for 8 h prior to
measurement of supernatant IL-8 by ELISA in triplicate (see Materials
and Methods). Cells exposed to 100 ng of PMA/ml were used as a positive
control. The data are expressed as the mean + standard error of
the mean of four separate experiments. (B) A549 cells were incubated as
described above with the indicated amounts of U0126 and stimulated with
Ad7 or PMA (100 ng/ml) for 4 h. IL-8 was measured in triplicate in
supernatants by ELISA and is given as nanograms per milliliter of
culture supernatant.
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To confirm whether the reduction in Ad7-stimulated IL-8 production
caused by PD98059 was due to inhibition of Erk, we repeated
this
experiment with an alternative MEK inhibitor, U0126 (
14,
17). As with PD98059, U0126 reduced but did not completely
abrogate
IL-8 induction by Ad7 (Fig.
5B). Taken together, the results
with
the two MEK inhibitors establish a causal relationship between
Ad7-induced Erk activation and subsequent IL-8
production.
PD98059 inhibition is reversible.
To determine if inhibition
of Erk activation and IL-8 induction by MEK inhibitor was due to
nonspecific toxicity of PD98059, we asked whether the effects of the
drug were reversible. A549 cells were incubated with 50 µM PD98059 or
DMSO for 30 min. At the end of the incubation time, the cells were
washed three times with PBS and resuspended in fresh medium lacking
drug or solvent. The cells were then incubated for 20 min in the
presence of either buffer, Ad7 at an MOI of 50, or PMA and processed
for assessment of Erk activity by immunoblot analysis. As shown in Fig.
6A and B, cells that were never exposed
to PD98059 demonstrated fourfold and eightfold induction of Erk
activity with Ad7 and PMA stimulation, respectively. Cells that had
been incubated with PD98059 and washed to remove the drug regained Ad7-
and PMA-inducible Erk activity, showing a five- and sevenfold
activation by Ad7 and PMA, respectively. Cells that were given PD98059
after being washed with PBS had background levels of Erk induction.
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FIG. 6.
PD98059 inhibition is reversible. Serum-starved A549
cells were preincubated with 50 µM PD98059 or diluent for 30 min and
then washed with PBS. The cells were exposed to Ad7 at an MOI of 50 or
to virus-free buffer for 20 min prior to the measurement of Erk
activation or for 24 h prior to the measurement of IL-8 release (see
Materials and Methods). Cells exposed to 100 ng of PMA/ml and cells
exposed to PMA immunoprecipitated with NRIg were used as positive and
negative controls, respectively. (A) Immunoblot of control,
Ad7-infected, or PMA-stimulated and washed cell extracts stained with
anti-phospho-Erk1/2 antibody (top) and same membrane stripped and
reprobed with anti-Erk1/2 antibody (bottom). The Erk experiment
included cells stimulated in the presence of PD98059 after being
washed. (B) Activation of Erk as determined by ratio of phospho-Erk to
total Erk for each immunoprecipitate. (C) IL-8 levels in supernatants
of cells treated as above. The data are the mean + standard error
of the mean of four separate experiments. +, present; , absent.
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In a separate set of experiments, we determined the reversibility of
PD98059 inhibition of IL-8 secretion. Figure
6C shows
that A549 cells
never exposed to PD98059 demonstrated 5- and 11-fold
increases in IL-8
with Ad7 and PMA stimulation, respectively.
The fold increases in
response to these stimuli were similar in
cells exposed to PD98059 and
washed prior to Ad7 and PMA treatment
(5- and 12-fold, respectively
[Fig.
6C]). These data support the
notion that the effects of
PD98059 on Erk and IL-8 induction are
unlikely to be due to
cytotoxicity but rather to a specific effect
on MEK
inhibition.
Erk induction is necessary for Ad7 induction of IL-8 promoter
activity.
Although Erk is important for the production of IL-8 in
response to Ad7 infection, it is unclear which stage of IL-8 production requires Erk. Activated Erk is known to translocate into the nucleus and cause the transactivation of genes through phosphorylation of
transcription factors. Since earlier studies indicated that Ad7
activated IL-8 mRNA production (7), we asked whether Erk activation was necessary for transcriptional upregulation of IL-8 mRNA.
To assess IL-8 promoter activity, we utilized the 162 to +44 IL-8Luc
reporter plasmid in transient-transfection assays (19).
A549 cells were transfected with reporter plasmid DNA and cotransfected
or not with cDNA encoding an inactive Ras mutant, N17Ras, to block
stimulation of Erk (26). The transfectants were either
mock infected or exposed to Ad7 for 6 h prior to lysis and
measurement of reporter gene expression. As shown in Fig. 7, mock-infected cells exhibited a basal
level of lucerifase activity, while Ad7 infection elicited a fivefold
increase in the amount of luciferase activity. In contrast, cells
cotransfected with N17Ras and the IL-8 reporter plasmid displayed
greatly reduced induction of luciferase by Ad7. Likewise, cells
transfected with reporter plasmid and preincubated with the MEK1
inhibitor U0126 prior to infection failed to induce luciferase activity
in response to Ad7 stimulation. These results confirm the necessary
role of Erk in IL-8 induction by Ad7 and further indicate that the
level of regulation of IL-8 production by Erk is, at least in part, at
the level of transcription.
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[in a new window]
|
FIG. 7.
Activation of IL-8 promoter activity by Ad7 is dependent
upon activation of Ras pathway. A549 cells were transfected with the
Gene Porter 2 system with either IL-8Luc alone or in combination with
N17Ras in fourfold excess. Cells were mock or Ad7 infected for 6 h, and luciferase activity was measured. One set of cells transfected
with 162 to +44 IL-8Luc alone was preincubated with the MEK inhibitor
U0126 (25 µM) for 30 min prior to mock or Ad7 infection.
|
|
Erk induction is necessary for Ad7-associated induction of
endogenous IL-8 mRNA levels.
We have also performed experiments to
confirm that stimulation of the IL-8 gene occurs at the level of
transcription and that inhibition of the Erk pathway acts at the
transcriptional level. In these studies, cells were exposed to Ad7 at
an MOI of 50 for 2 h in the presence or absence of 25 µM
PD98059, mRNA was harvested, and IL-8 mRNA levels were determined by
Northern analysis. The results (Fig. 8)
demonstrate an approximately eightfold induction of endogenous IL-8
mRNA levels by Ad7. This is similar to the level of IL-8 promoter
activation seen, and coupled with our previous data showing that IL-8
message stability is enhanced less than twofold by Ad7, suggests that
activation of IL-8 by Ad7 occurs mostly at the level of transcription.
View larger version (52K):
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|
FIG. 8.
Induction of endogenous IL-8 mRNA levels by Ad7 is
inhibited by PD98059. A549 cells were exposed to Ad7 at an MOI of 50 for 2 h in the presence or absence of 25 µM PD98059. PMA (100 ng/ml) was used as a positive control. RNA was extracted and prepared
for Northern analysis as described in Materials and Methods. (A) RNA
blot probed for IL-8 mRNA. (B) RNA gel of the blot in panel A stained
with ethidium bromide. (C) IL-8 mRNA levels expressed as a ratio of
IL-8 mRNA to rRNA visualized for each condition.
|
|
Preincubation of Ad7-stimulated cells with PD98059 inhibited this
induction by 90%. Thus, inhibition of Erk pathway activation
by
PD98059 likely acts at the transcriptional level by
inhibiting
Erk-modulated IL-8 promoter activation. This
prevents the enhancement
of endogenous IL-8 mRNA levels by
Ad7.
| |
DISCUSSION |
Host cells respond to acute infectious agents by activation of
cellular signaling pathways and by the production of inflammatory mediators necessary to eliminate the pathogen. We sought to determine whether induction of the inflammatory mediator IL-8 by Ad infection of
human epithelial cells involves the Erk1/2 pathway. Our findings presented here demonstrate that IL-8 induction requires activation of
Erk. First, Ad7 infection of A549 human lung epithelial cells provoked
a rapid stimulation of Erk enzymatic activity, assessed by two
independent methods. Second, increasing inhibition of Ad7-induced Erk
activation by the MEK inhibitor PD98059 or U0126 correlated with
increased inhibition of Ad7-induced IL-8. Additionally, Ad7 infection
of A549 cells stimulated the IL-8 promoter, indicating that Ad7
infection elicits nascent mRNA encoding IL-8. Most importantly, inhibition of the Erk signaling pathway in A549 cells using a dominant-negative Ras in transient-transfection assays resulted in
abrogation of IL-8 promoter induction by Ad7.
These findings are consistent with a model in which Ad7 stimulates the
Ras pathway in host cells, resulting in the activation of Erk.
Activated Erk stimulates the IL-8 promoter to elicit nascent IL-8 mRNA
and protein. The IL-8 protein is secreted by virus-infected cells to
produce an inflammatory response. The data provide insight into
the cellular mechanisms of host response to wild-type Ad infection
known to result in robust inflammation. Furthermore, the results
suggest possible mechanisms for inhibiting the inflammatory response to
the virus during gene therapy protocols involving Ad vectors.
Although it is unclear how the virus initiates this host response, we
hypothesize that activation of Erk, with subsequent induction of IL-8
and inflammation, is an event driven by Ad7 interaction with host
receptors. This notion is supported by the rapid kinetics of Erk
phosphorylation, which peaks within 10 min of Ad7 contact with cells.
Furthermore, the hypothesis is consistent with the findings of other
groups studying the induction of cytokines by recombinant Ad vectors.
In these examples, induction of the cytokine IP-10 could be measured in
cells infected with Ad in which the viral genome had been inactivated
by radiation (8, 34). The initial steps of Ad infection
involve attachment of the globular head of the Ad fiber to a cellular
receptor, followed by interaction of the penton base of the virus with
a host cell integrin receptor through an arginine-glycine-aspartic acid
(RGD) motif (40). Subgroup B viruses, such as Ad7, have
been reported to interact with the same
v
3 and v5
integrins utilized by the other Ad serotypes (32).
However, Ad7 and other subgroup B viruses do not utilize the
coxsackievirus and adenovirus receptor utilized by most other Ad
serotypes as the fiber receptor (37). The use of alternate
fiber receptors may influence intracellular trafficking of Ad
serotypes. Thus, Ad5f7 chimeras, containing the Ad5 capsid
with Ad7 fibers, progress through the cytoplasm in a manner similar to
that of the Ad7 virus and distinct from that of the Ad5 virus
(33). The induction of signal transduction pathways and
inflammatory mediators by Ad7 may be the result of stimulation of
receptors distinct from those used by other Ad subgroups.
Although our data indicate that induction of the Erk pathway is
essential for Ad7-mediated induction of IL-8 mRNA, it is possible that
other signal transduction pathways are also involved. This is suggested
by the fact that levels of the MEK inhibitors that completely eliminate
Erk activation were not entirely sufficient to eliminate IL-8
secretion. Because Ad internalizes through an integrin
ligation-mediated process, it is likely that signal transduction events
associated with integrin function are activated during Ad
internalization. For example, Ad2 induces the activation of phosphatidylinositol 3-kinase, which accompanies viral endocytosis by
human epithelial cells (28). Ad infection likewise
activates an Src kinase, p125 focal adhesion kinase, and
p130Cas (29). These proteins form a signaling
complex that presumably leads to activation of additional signal
transduction pathways besides one involving Ras/Raf/MEK and Erk
(29). Additional signal transduction pathways induced by
Ad7 might similarly contribute to the production of inflammatory
mediators by host cells. IL-8 induction by other pathogens has been
shown to require activation of the p38 MAPK (2, 18, 31).
We are presently investigating the role of other pathways, including
p38 MAPK, in the induction of the IL-8 promoter by Ad7.
The results reported here reveal that infection of lung epithelial
cells with Ad7 results in the production of IL-8, and the attendant
lung inflammation, through a signal transduction process that involves
the Ras/Raf/MEK/Erk pathway. Erk appears to regulate IL-8 production at
the level of transcription. It seems unlikely that Ad7 stimulates
secretion of preformed IL-8 in host cells, since IL-8 mRNA levels in
uninfected cells are much lower than those seen after Ad7 infection
(7). Furthermore, our finding that Ad7 stimulates the IL-8
promoter in A549 cells is not consistent with a model in which host
cells secrete preformed IL-8. However, none of our experiments
specifically address secretion of preformed IL-8. An additional
possibility is that virus internalization by host cells and not
receptor triggering per se is the essential event leading to IL-8
production. The findings reported here cannot eliminate this
possibility, and we are investigating the issue. Differences in fiber
receptors on host cells for different Ad serotypes may explain why
wild-type Ad5 does not induce clinically significant inflammation in
the lower respiratory tract (7). However, Erk activation
and IL-8 production were reported when epithelial cells were infected
with E1-, E3-, and E4-deficient Ad5 (10), but IL-8 is not
induced upon infection with wild-type Ad5 (7). Hence, the
use of different receptors alone does not account for differences in
host responses upon infection of host cells by the various Ad
serotypes. Deciphering the role of Ad receptor interactions, signal
transduction pathways, and induction of the inflammatory response will
be especially important for the future design of gene therapy vectors
and treatment protocols for Ad infections.
| |
ACKNOWLEDGMENTS |
J. P. Metcalf is supported by NIH K08-HL03106 from the
NHLBI, an American Heart Association Heartland Affiliate Grant, and a
Presbyterian Health Foundation Grant. K. M. Coggeshall is a Scholar of the Leukemia & Lymphoma Society (formerly Leukemia Society of America).
We acknowledge the assistance of Gary Kinasewitz and Linda Thompson for
review of the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: OU Health
Sciences Center, 800 N. Research Pkwy., Oklahoma City, OK 73104. Phone:
(405) 271-6173. Fax: (405) 271-5440. E-mail:
jordan-metcalf{at}ouhsc.edu.
| |
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Journal of Virology, July 2001, p. 6450-6459, Vol. 75, No. 14
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.14.6450-6459.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Top
Abstract
Introduction
