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Journal of Virology, September 2001, p. 7828-7839, Vol. 75, No. 17
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.17.7828-7839.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Salicylates Inhibit Flavivirus Replication
Independently of Blocking Nuclear Factor Kappa B Activation
Ching-Len
Liao,1,*
Yi-Ling
Lin,1,2
Bi-Ching
Wu,1
Chang-Huei
Tsao,3
Mei-Chuan
Wang,1
Chiu-I
Liu,4
Yue-Ling
Huang,4
Jui-Hui
Chen,1
Jia-Pey
Wang,1 and
Li-Kuang
Chen5
Department of Microbiology and
Immunology,1 Institute of Preventive
Medicine,4 and Graduate Institute of
Life Science,3 National Defense Medical
Center, Institute of Biomedical Sciences, Academia
Sinica,2 and Department of
Immunology, Buddhist Tzu-Chi Medical College,5
Taiwan, Republic of China
Received 6 November 2000/Accepted 24 May 2001
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ABSTRACT |
Flaviviruses comprise a positive-sense RNA genome that replicates
exclusively in the cytoplasm of infected cells. Whether flaviviruses
require an activated nuclear factor(s) to complete their life cycle and
trigger apoptosis in infected cells remains elusive. Flavivirus
infections quickly activate nuclear factor kappa B (NF-
B), and
salicylates have been shown to inhibit NF-B activation. In this
study, we investigated whether salicylates suppress flavivirus
replication and virus-induced apoptosis in cultured cells. In a
dose-dependent inhibition, we found salicylates within a range of 1 to
5 mM not only restricted flavivirus replication but also abrogated
flavivirus-triggered apoptosis. However, flavivirus replication was not
affected by a specific NF-B peptide inhibitor, SN50, and a
proteosome inhibitor, lactacystin. Flaviviruses also replicated and
triggered apoptosis in cells stably expressing IB
-
N, a
dominant-negative mutant that antagonizes NF-B activation, as
readily as in wild-type BHK-21 cells, suggesting that NF-B activation is not essential for either flavivirus replication or
flavivirus-induced apoptosis. Salicylates still diminished flavivirus
replication and blocked apoptosis in the same IB-N cells. This
inhibition of flaviviruses by salicylates could be partially reversed
by a specific p38 mitogen-activated protein (MAP) kinase inhibitor,
SB203580. Together, these results show that the mechanism by which
salicylates suppress flavivirus infection may involve p38 MAP kinase
activity but is independent of blocking the NF-B pathway.
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INTRODUCTION |
Flavivirus is a genus of
the Flaviviridae family, which consists of more than 68 members. Most flaviviruses are arthropod borne and are capable of
infecting their vertebrate hosts through persistently infected mosquito
or tick vectors, such as Japanese encephalitis virus (JEV), tick-borne
encephalitis virus, and dengue viruses (DEN). The enveloped virion of a
flavivirus contains a single-stranded, positive-sense RNA genome of
approximately 11 kb, whose replication is primarily cytoplasmic and
membrane associated. All known viral proteins are derived from a
polyprotein that is expressed from the single open reading frame (ORF)
on the flavivirus genome. The structural proteins of flaviviruses,
including those of the capsid (C), membrane (M), and envelope (E), are
encoded in the 5' quarter of the ORF, and the nonstructural proteins, namely, NS1 through NS5, are encoded in the rest. In common with other
animal positive-sense RNA viruses with a single ORF, the first event of
flavivirus replication in infected cells after uncoating is to
translate the message-sense RNA genome into a polyprotein, which is co-
and/or posttranslationally processed into 10 individual proteins by
cellular and viral proteases. Flavivirus particles mature predominantly
on intracellular membranes of the cytosol, but not on plasma membranes,
of infected cells. Pirating the same intrinsic secretory pathway
normally employed by cells to discharge macromolecules, flaviviruses
bud from membranes of the endoplasmic reticulum and Golgi apparatus in
infected cells to release the mature virions (for reviews, see
references 12 and 66). As a result of infection, some
flaviviruses cause the infected host cells severe cytopathic effects
(CPE). JEV (43) and DEN (2, 21, 22), for
example, have been shown to induce infected cells to undergo apoptotic
cell death, which is one of the mechanisms that contribute to
flavivirus-induced CPE.
As a part of the cellular response system, nuclear factor kappa B
(NF-B) acts as an inducible transcription factor that can be quickly
activated in response to many noxious stimulants, including virus
infections. Normally sequestered by forming a complex with one of its
cytoplasmic inhibitors, NF-B actually preexists in the cytoplasm of
most cell types as an inactive homodimer or heterodimer comprised of
one or two of five different subunits, including p50 (NF-B1), p52,
p65 (RelA), c-Rel, and RelB. Upon signaling by different stimuli, the
activation cascade of NF-B involves phosphorylation and degradation
of the IB (inhibitor of NF-B) proteins, thereby releasing NF-B
from cytoplasmic complexes; NF-B then translocates into the nucleus
and binds to its cognate DNA sequences. Consequently, the expression of
NF-B-dependent genes results in the generation of numerous mediators
important for malignant transformation, cell adhesion, cell growth
control, apoptosis control, immune functions, and embryonic development (for reviews, see references 3 and 5). In addition,
NF-B may also play a crucial role against viruses, as NF-B
activation can induce expression of the genes for beta interferon,
major histocompatibility complex class I, and several inflammatory
cytokines (for a review, see reference 4). On the other
hand, a wide variety of viruses from various viral families are capable
of activating NF-B in infected cells, including cytomegalovirus (CMV) (69), human immunodeficiency virus type 1 (68), Sendai virus (25, 68), adenovirus
(17), hepatitis B virus (15, 50), human
T-lymphotropic virus type 1 (26, 28, 54, 58), Epstein-Barr
virus (32, 40), influenza virus (60), Sindbis virus (44, 45), and DEN serotype 1 (DEN-1)
(52). For Sindbis virus or DEN-1, both of which are
single-stranded, positive-sense RNA viruses, apoptotic cell death
triggered by infections is facilitated by NF-B activation (44,
45, 52). Because NF-B activation is an active cellular
process, it is conceivable that some of these viruses may derive
certain replication advantages from expression of NF-B-dependent
genes in infected cells. Nevertheless, little is known about whether a
cytoplasmic RNA virus requires activation of other nuclear-factors to
complete its life cycle in infected cells. This prompted us to
investigate in the present study whether NF-B activation in infected
cells is essential for flavivirus replication and for
flavivirus-induced apoptosis.
Salicylates are widely employed as nonsteroidal anti-inflammatory
drugs. In addition to blockage of prostaglandin production by
inhibition of cyclooxygenase (COX), sodium salicylate (NaSal) and
acetylsalicylic acid (aspirin) also inhibit NF-B activation induced
by tumor necrosis factor (TNF) and some other agents, most likely by
preventing the phosphorylation of IB and its subsequent
degradation by the ubiquitin-proteasome pathway (6, 9, 29, 39,
59, 61, 62). Furthermore, the inhibitory effects of salicylates
on TNF-induced phosphorylation and degradation of IB appear to
also involve the activation of p38 mitogen-activated protein kinase
(MAPK) (70), which is a member of the three structurally related MAPK families identified in mammalian cells. Treatment with
salicylates alone was shown sufficient to produce strong p38 MAPK
activation in human FS-4 fibroblasts and African green monkey kidney
COS-1 cells (70, 71). Hence, besides COX inhibition, the
inhibition of NF-B activation or the induction of p38 MAPK activation might be equally important in the pharmacological actions of salicylates.
Both NaSal and aspirin attenuate the gene expression and infectivity of
human CMV in coronary artery smooth muscle cells, probably through the
COX-2- or NF-B-dependent pathway (73). However, the
mechanism by which salicylates act against the replication of RNA
viruses remains poorly defined and may utilize strategies fundamentally
different from those for antagonizing DNA viruses such as CMV.
In this study, we explored the effects of NaSal and aspirin on the
replication of JEV and DEN-2 in cultured cells. Our results revealed
that salicylates not only suppress the replication of JEV and DEN-2 in
a dose-dependent manner but also prevent apoptosis of infected cells.
Salicylates had only trivial effects on the replication of Sindbis
virus, a prototype of the Alphavirus family, under the same
conditions. The inhibitory effects of salicylates on flaviviruses did
not appear to result from suppression of NF-B activation but instead
were at least partially due to the activation of p38 MAPK given that
the pyridinyl imidazole compound SB-203580, a highly selective p38 MAPK
inhibitor, was able to alleviate the antiflavivirus effects of
salicylates. In addition, the flaviviruses seemed not to require
NF-B activation in order to replicate in infected cells, since
several blocking approaches all failed to influence flavivirus
production. Our results suggest that salicylates utilize an
NF-B-independent pathway, which may involve p38 MAPK activity, to
interfere with flavivirus replication and thereby delay the process of
virus-associated apoptosis.
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MATERIALS AND METHODS |
Viruses, cell lines, and chemicals.
A plaque-purified
Taiwanese JEV strain, RP-9 (13, 14), was employed
throughout this study. The propagation of JEV was carried out in baby
hamster kidney (BHK)-21 cells utilizing RPMI 1640 medium containing 2%
fetal calf serum (FCS; GIBCO). A local Taiwanese strain of DEN-2,
PL046, isolated from a dengue fever patient was generously provided by
the National Institute of Preventive Medicine, Taiwan, Republic of
China (ROC). DEN propagation was carried out in C6/36 cells utilizing
RPMI 1640 medium containing 5% FCS (GIBCO). In some experiments
Sindbis virus (Ar-339; American Type Culture Collection) was used to
infect the target cells. The propagation of Sindbis virus was carried
out in BHK-21 or Chinese hamster ovary (CHO) cells utilizing RPMI 1640 medium containing 2% FCS. N18, a mouse neuroblastoma cell line
(1) (kindly provided by D. E. Griffin, Johns Hopkins
University, Baltimore, Md.), was grown in RPMI 1640 medium containing
10% FCS (GIBCO). NaSal and aspirin were purchased from Sigma. The
NF-B peptide inhibitor SN50, its ineffective analogue SN50M, and
phorbol 12-myristate 13-acetate (PMA) were obtained from Calbiochem.
Lactacystin and indomethacin were acquired from Biomol.
Virus infection and titration.
For infection with JEV or
DEN, monolayers of the indicated cells grown in 6- or 12-well plates
were initially adsorbed with virus at a multiplicity of infection (MOI)
of 5 for 1 h at 37°C. After adsorption, the unbound viruses were
removed by three gentle washings with serum-free RPMI 1640 medium.
Fresh medium containing 2% FCS was added to each plate for further
incubation at 37°C. At the end of infection, the culture media were
harvested for a plaque-forming assay to determine virus titers.
Briefly, a virus dilution was added to 80% confluent BHK-21 cells and
incubated at 37°C for 1 h. After adsorption, the cells were
washed and overlaid with 1% agarose (SeaPlaque; FMC BioProducts)
containing RPMI 1640 with 1% FCS. After incubation for 4 (for JEV) or
7 (for DEN) days, the resulting cells were fixed with 10% formaldehyde
and stained with 0.5% crystal violet for plaque counting. Virus titers
were expressed as PFU per milliliter.
Western immunoblot analysis.
Cell lysates were prepared in a
lysis buffer (1% Nonidet P-40, 150 mM NaCl, 50 mM Tris-HCl [pH 7.5],
1 mM EDTA) containing a cocktail of protease inhibitors (20 µg of
phenylmethysulfonyl fluoride per ml, 2 µg of leupeptin per ml, 2 µg
of aprotinin per ml). Lysates were mixed with an equal volume of sample
buffer with 2-mercaptoethanol, separated by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), and transferred
to a nitrocellulose membrane (Hybond-C Super; Amersham). The
nonspecific antibody-binding sites were blocked with 5% skim milk in
phosphate-buffered saline (PBS), and the membranes were reacted with
monoclonal antibodies specific for JEV E or NS1 (13). The
resulting blot was treated with a horseradish peroxidase-conjugated
goat anti-mouse immunoglobulin (Cappel) and developed with ECL reagent (Amersham).
MTT assay.
An MTT
[3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-2H-tetrazolium bromide]
assay was used to measure mitochondrial functions, which served as an
index of living cells. The assay was carried out as previously
described (46, 71) with minor modifications. Briefly, MTT
(Sigma) was dissolved in 0.1 M Tris-buffered saline to make a 5-mg/ml
solution, which was then filtered to remove insoluble residues. Fifty
microliters of MTT solution was added to each well containing tested
cells in a 12-well plate and incubated at 37°C for 4 h. At the
end of incubation, the MTT solution was removed, and 500 µl of
isopropanol containing 0.04 N HCl was added to dissolve the dark-blue
crystals precipitated in the wells. A 100-µl portion of the resulting
solution was removed from each well and read at 540 nm on a microplate
reader (Dynatech MR5000).
DNA fragmentation assay.
Low-molecular-weight DNA was
extracted from apoptotic cells following the published method
(65). Briefly, cell suspensions in Hanks buffered salt
solution (HBSS) were incubated with 70% ethanol for 24 h at
20°C. The resulting cells were centrifuged to remove ethanol, and
the cell pellets were resuspended and incubated in 40 µl of PC buffer
(192 mM Na2HPO4 mM citric acid [pH 7.8]) at
room temperature (RT) for 30 min. After centrifugation at
1,000 × g for 5 min, the supernatants were collected
and vacuum concentrated in new microcentrifuge tubes for 15 min using a
SpeedVac. Three microliters of NP-40 solution (0.25%) and 3 µl of
RNase A solution (1 mg/ml) were then added and incubated at 37°C for
30 min. After incubation, 3 µl of proteinase K solution (1 mg/ml) was
added and the mixture was further incubated at 37°C for 30 min. The resulting DNA-containing extracts were then analyzed by 2% agarose gel
electrophoresis in 1× Tris-borate-EDTA (TBE) buffer using ethidium bromide (EtBr) staining.
Cellular DNA fragmentation ELISA.
Levels of apoptotic cell
death were measured by a quantitative sandwich enzyme immunoassay using
a commercial kit (Cellular DNA Fragmentation ELISA; Boehringer
Mannheim). Cells were labeled with bromodeoxyuridine (BrdU) overnight
prior to virus infection. At the various indicated time points
postinfection, cells were permeabilized to release the cytoplasmic DNA
fragments into the supernatant. The amounts of BrdU-labeled DNA
released were measured by an enzyme-linked immunosorbent assay (ELISA)
reader (Microplate reader; Molecular Devices) using antibodies against
DNA and BrdU.
RNA dot blotting and [3H]uridine
incorporation.
For RNA preparation, the published method
(16) was followed; briefly, cell monolayers in 60-mm
dishes were first incubated with RNA lysis buffer (4 M guanidine
thiocyanate, 25 mM sodium citrate [pH 7.0], 10 mM
-mercaptoethanol, 0.5% N-lauroylsarcosine) for 15 min at
4°C. Cell lysates were extracted twice with acid pheno-chloroform
(1:1), and RNA in the aqueous phase was then collected and precipitated
by alcohol. Appropriate amounts of RNA from each sample were twofold
serially diluted with RNA dilution buffer (diethylpyrocarbonate
[DEPC]-treated H2O-20× SSC [1× SSC is 0.15 M
NaCl plus 0.015 M sodium citrate {pH 7.0}]-formaldehyde [5:3:2]) and then applied to a nylon membrane (Boehringer Mannheim) using a dot blotting manifold (Pierce). The resulting RNA samples on
the membrane were fixed by UV cross-linking, blotted, and detected by a
digoxigenin (DIG) nonradioactive nucleic acid labeling and detection
system (Boehringer Mannheim) according to the manufacturer's instructions. Briefly, the filter was prehybridized with DIG Easy Hyb
solution (Boehringer Mannheim) at 50°C for 1 h before the probe
was added and hybridized overnight. DIG-11-dUTP was incorporated into
the DNA probe by Taq polymerase during PCR. To obtain the DIG-labeled DNA probe specific for JEV, a plasmid containing the JEV
NS1 gene was used as the template for PCR with a primer set hybridized
to nucleotides 2478 (positive sense)
(5'-GCGATCCAGACACTGGATGTGCCA-3') and 3534 (negative sense)
(5'-GCGGATCCTAAGCATCAACCTGTGA-3') of the JEV cDNA. After
overnight hybridization, the filter was washed twice for 5 min in 2×
SSC-0.1% SDS at RT and twice for 15 min in 0.1× SSC-0.1% SDS at
68°C. To detect the RNA-DNA binding signal on the filter, an anti-DIG
antibody-alkaline phosphatase conjugate was used to bind to the
hybridized probe, and the signal was detected by exposing the filter to
X-ray film in the presence of the chemiluminescence substrate CSPD
(Roche Molecular Biochemicals).
To incorporate [3H]uridine, infected cells were first
treated with actinomycin D at 2 µg/ml for 1 h and then labeled
with [3H]uridine (Amersham) at 10 µCi/ml in culture
medium for another 1 h. Actinomycin D was used to reduce
polII RNA synthesis so that the signal from
polII-independent RNA synthesis and viral RNA replication
could be readily detected. The total cellular RNAs were isolated with
NET buffer (50 mM Tris-HCl [pH 7.75], 150 mM NaCl, 0.1% NP-40, 1 mM
EDTA) plus 2% SDS and precipitated on glass fiber diss (GF/C;
Whatman) with a trichloroacetic acid (TCA) solution (5% TCA and 20 mM
sodium pyrophosphate). The disks were washed with 70% ethanol and
dried at RT. [3H]uridine incorporation was measured with
a -counter (Beckman) using scintillation fluid (Biofluor; Dupont, NEN).
LDH assay.
Cell viability was assessed by the release of the
cytoplasmic enzyme lactate dehydrogenase (LDH) using a commercial kit
(Cytotoxicity Detection Kit; Boehringer Mannheim) following the
manufacturer's instructions. Briefly, the culture supernatants from
cell samples were clarified by centrifugation, mixed with the reaction
mixture (diaphorase-NADH+, tetrazolium salt INT-sodium
lactate), incubated at RT for about 30 min, and then read by an ELISA
reader at 490 nm (Microplate reader; Molecular Devices).
Determination of luciferase activity.
Cells were transiently
transfected with a reporter plasmid, pNFB-Luc (Stratagene), carrying
the luciferase gene downstream of the NF-B promoter. After 18 h, the cells were infected by JEV at an MOI of 5, and at 6 h
postinfection the resulting cells were harvested and lysed to determine
luciferase activity by using a Luciferase Assay System kit purchased
from Promega. To examine the salicylate effect, in some indicated
experiments the cells were also treated with 5 mM NaSal. Luciferase
activity was expressed as relative light units.
Establishment of cell clones permanently expressing
IB-N.
All cell lines stably expressing IB-N were
cloned from single cells by the limiting-dilution method as previously
described (13). To establish cell clones stably expressing
IB-N, 60% confluent BHK-21 cells were transfected by
Lipofectamine (BRL) with the human IB-N expression plasmid
pCMV4/IB-N (11). The transfected cells were
selected and cloned in the presence of Geneticin (GIBCO). The
expression of IB-N in cell clones was assessed by Western
blotting, using an antibody specific for the human IB-N
protein (Santa Cruz). The resultant clones were cultured in RPMI 1640 medium containing 5% FCS.
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RESULTS |
NaSal and aspirin inhibit the replication of flavivirus, but not
that of Sindbis virus, in BHK-21 cells and N18 mouse neuroblastoma
cells.
Both BHK-21 and N18 cells can support the productive
replication of JEV and DEN-2 (13, 47), and the severe CPE
induced by the viruses lead to cell death through a mechanism probably involving apoptosis (43). To study the effects of NaSal
and aspirin on JEV replication, BHK-21 fibroblasts were first infected with RP-9, a neurovirulent strain of JEV (14), at an MOI
of 5, and after 1 h of virus adsorption the infected cells were
washed and incubated in the presence of varying amounts of salicylates for 48 h. A concentration of salicylates between 1 and 5 mM was chosen for subsequent experiments because this is the actual serum range suggested for patients treated for chronic inflammatory diseases,
and concentrations higher than 6.5 mM have been proven to be too toxic
for clinical use (34). As Fig.
1A indicates, within the range of 1 to 5 mM the addition of NaSal or aspirin to the culture medium inhibited JEV
replication in a dose-dependent manner. To determine whether or not the
antiviral effects of NaSal and aspirin were due merely to the cytotoxic
effect of salicylates on BHK-21 cells, an MTT assay was
performed to evaluate mitochondrial activity (46) as a
viability index for salicylate-treated cells. Figure 1B shows that no
significant difference in mitochondrial function was detectable
among cells treated with salicylates at concentrations ranging from 1 to 5 mM. In addition, salicylate by itself did not appear to have any
direct anti-JEV capability, since pretreatment of JEV stocks with 5 mM
NaSal or aspirin for 1 h at 37°C did not affect virus
infectivity (data not shown). These results indicated that it was the
infected BHK-21 cells that were targeted by salicylates to result in an
inhibitory effect on JEV replication. Since we previously demonstrated
that JEV could cause severe CPE of infected cells (43),
the effects of salicylates on JEV-induced CPE were examined.
Morphologically, at 36 h postinfection, CPE resulting from JEV
infection were evident in the BHK-21 cells without salicylate
treatment, whereas the infected, salicylate-treated BHK-21 cells
appeared to be more resistant to virus-induced cytopathic damage (data
not shown). The magnitude of cellular damage was then quantified by
measuring the amount of LDH, a cytoplasmic enzyme, that had leaked into the culture medium from tested cells. As shown in Fig. 1C, at 36 h
postinfection, the release of LDH from JEV-infected cells gradually
declined as the concentration of NaSal or aspirin increased, consistent
with the antiviral phenomenon seen in Fig. 1A. This result suggested
that salicylates alleviated the JEV-triggered CPE in the infected
BHK-21 cells in a dose-dependent fashion.
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FIG. 1.
NaSal and aspirin inhibit flavivirus replication in
BHK-21 and N18 cells. (A) BHK-21 cells were infected by JEV at an MO1
of 5, and at 1 h postinfection, the infected cells were treated
with varying concentrations of NaSal (SA) or aspirin (ASA). After a
48-h incubation at 37°C, the virus titers (expressed as PFU per
milliliter) in the culture media were determined by a plaque forming
assay as described in Materials and Methods. Values of virus titers are
shown as means ± standard errors of the means for three
independent experiments. (B) MTT assay of salicylate-treated BHK-21
cells. BHK-21 cells were treated with SA or ASA at the indicated
concentrations for 48 h at 37°C, and the viabilities of the
resulting cells were determined by an MTT assay. (C) LDH release assay.
At 32 h postinfection, amounts of LDH released from the JEV-infected
BHK-21 cells treated with varying amounts of salicylates were measured
by an ELISA plate reader at 490 nm. Optical densities at 490 mm are
shown as means for representative experiments performed in triplicate.
(D) BHK-21 cells were infected by DEN at an MO1 of 5 and were treated
with varying concentrations of SA or ASA as indicated. After a 48-h
incubation at 37°C, the virus titers (in PFU per milliliter) in the
culture media were determined as described for panel A). (E) N18 cells
were infected by DEN and treated with SA or ASA. After a 48-h
incubation at 37°C, the virus titers (in PFU per milliliter) in the
culture media were determined as described for panel A.
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We also investigated the effects of salicylates on JEV replication in a
murine neuroblastoma cell line N18. Within the 1 to
5 mM range, the
presence of NaSal or aspirin in the media of JEV-infected
cells
exhibited an antiviral effect in a dose-dependent manner,
and at higher
concentrations (3 to 5 mM), aspirin seemed to be
slightly more
effective than NaSal as an inhibitor of JEV replication
(data not
shown). In addition, in agreement with our observations
for BHK-21
cells, salicylates also appeared to reduce JEV-induced
CPE in N18
cells; likewise, a similar inhibitory effect of salicylates
on JEV
replication was noticed with other cell types tested, including
Vero,
COS-7, and mouse astrocytoma DBT cells (data not shown).
Since this
inhibition was not restricted to one cell type, the
salicylate-mediated
anti-JEV effect seemed to operate in a cell
type-independent
manner.
We next explored whether salicylates can also block the replication of
DEN, another member of the mosquito-borne flaviviruses,
in cultured
cells. BHK-21 or N18 cells were infected by a human
DEN-2 isolate,
PL046, at an MOI of 5, and the infected cells were
then incubated for
appropriate periods with various concentrations
of NaSal or aspirin. At
48 h postinfection the number of infectious
virus particles
released into the culture medium was determined.
As Fig.
1D shows, both
NaSal and aspirin hindered the replication
of DEN-2 in BHK-21 cells in
a concentration-dependent fashion.
Similarly, salicylates also
inhibited the replication of DEN-2
in N18 cells (Fig.
1E). Taken
together, these results showed that
salicylates possessed an
antiflavivirus effect on this cell culture
system. This observation
raises the possibility that salicylates
may also be capable of
hampering the replication of other RNA
viruses in addition to
flaviviruses in cultured cells. To address
this issue, another
positive-sense RNA virus, Sindbis virus (Ar-339;
American Type Culture
Collection), which is a prototype of the
Alphavirus family,
was examined under the conditions described
above. We found that after
18 h of incubation, neither NaSal nor
aspirin had an inhibitory
effect on Sindbis virus replication
in BHK-21 or N18 cells. There was
no apparent difference in virus
production between infected cells that
were treated with salicylates
and those that were not, even at a
concentration of 5 mM (data
not shown). These salicylates also failed
to suppress Sindbis
virus-induced CPE in both cell types (data not
shown). These results
indicate that the inhibitory effects of
salicylates are not universal
among RNA viruses. The inhibition of
flaviviruses, but not alphaviruses,
by salicylates is likely due to the
difference in the modes of
virus replication between flaviviruses and
alphaviruses in infected
cells.
Effects of salicylates on synthesis of viral RNA in JEV-infected
N18 cells.
To further characterize the mechanism of
salicylate-mediated inhibition, the effects of NaSal on viral RNA
synthesis in JEV-infected N18 cells were investigated. Total viral RNA
isolated from RP-9-infected, NaSal-treated N18 cells was quantitated by
RNA dot blot analysis using a double-stranded DNA probe specific for
the JEV NS1 region (46). As Fig.
2A shows, at 18 h postinfection the
amounts of total viral RNA were gradually reduced as the dose of NaSal
in the culture medium increased, indicating that salicylate decreased the amount of viral RNA accumulation. As a control, the total amounts
of polII-independent RNA synthesis, as detected by
[3H]uridine incorporation, did not differ significantly
among JEV-infected N18 cells treated with varying concentrations of
NaSal (Fig. 2B). These results thus suggest that NaSal exerted its
antiflavivirus activity by interfering specifically with flavivirus RNA
synthesis in the infected cells.
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FIG. 2.
Effects of NaSal on viral RNA synthesis in JEV-infected
N18 cells. (A) RNA dot blotting. Total RNAs were isolated at 18 h
postinfection from JEV-or mock-infected N18 cells treated with various
doses of NaSa1 (SA) as indicated. Appropriate amounts of RNA from each
sample were threefold serially diluted (marked as 1 to 1/27 on the left
of the panel) and applied to a nylon membrane that was then hybridized
with the DIG-labeled DNA probe specific for the JEV NS1 region. (B)
[3H]uridine incorporation. JEV-infected N18 cells were
treated with varying doses of SA and incubated for 17 h at 37°C.
After the resulting cells were labeled with [3H]uridine
for 1 h, the newly synthesized, actinomycin D-resistant RNA was
isolated. One-tenth of the cell lysates from each sample was counted
for incorporation of [3H]uridine into RNA as described in
Materials and Methods.
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Effects of salicylates on synthesis of JEV glycoproteins.
Both
E and NS1 proteins of JEV are glycoproteins that can be secreted into
culture media during infection (13). To determine whether
or not salicylates can influence the synthesis of viral proteins, the
amounts of viral glycoproteins accumulating intracellularly or released
extracellularly from JEV-infected BHK-21 or N18 cells were determined
by Western blot and densitometry analysis using monoclonal antibodies
specific for viral E and NS1 glycoproteins. The accumulation of
intracellular (Fig. 3A) or extracellular
(Fig. 3B) E proteins from both BHK-21 and N18 cells was only slightly affected by different concentrations of NaSal. In contrast, upon NaSal
treatment, the amounts of intracellular (Fig. 3A), as well as
extracellular (Fig. 3B), NS1 proteins accumulating from JEV-infected cells decreased as the NaSal concentration gradually increased. This
inhibitory effect of NaSal on viral protein synthesis was not likely
due to its cytotoxic effect on the infected cells, since total protein
synthesis, as measured by [35S]methionine incorporation,
did not differ significantly among cells treated with varying amounts
of NaSal or between treated and untreated cells (data not shown). These
data suggest that NaSal may either diminish the amount of NS1
glycoproteins synthesized intracellularly or block the secretion of
these glycoproteins from JEV-infected cells. Still, it remains unclear
why NaSal selectively influenced the accumulation of JEV NS1 more than
that of E or NS1' proteins in infected cells. Whether NaSal affects the
stability of NS1 protein at a posttranslational level during JEV
replication requires further study. In addition, why NaSal could
inhibit viral RNA synthesis (Fig. 2A) more strongly than viral
glycoprotein synthesis (Fig. 3), especially at 1 mM NaSal, remains
unclear and needs to be addressed thoroughly in future experiments.
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FIG. 3.
Effects of NaSal on synthesis of JEV glycoproteins in
infected BHK-21 and N18 cells. Immunoblot analysis of JEV E or NS1
protein in cell lysates (A) or in supernatants (B) from BHK-21 (lanes 1 to 6) or N18 cells (lanes 7 to 12) cells treated with doses of NaSa1
(SA) ranging from 0 to 5 mM as indicated. NS1' is the longer version of
the NS1 protein derived from an aberrant cleavage in the JEV-infected
cells (36).
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Salicylates suppress flavivirus-induced apoptosis in cultured
cells.
Since JEV infection triggers apoptotic cell death
(43), we investigated whether salicylates are capable of
preventing infected cells from undergoing JEV-induced apoptosis. JEV
strain RP-9 (at an MOI of 5) was used to infect BHK-21 or N18 cells. At
32 h postinfection, low-molecular-weight DNA was isolated from
mock- or JEV-infected cells treated with varying amounts of
salicylates, and cells were then examined using agarose gel
electrophoresis. As a control, a DNA sample derived from BHK-21 cells
infected with JEV exhibited characteristic internucleosomal size
laddering (Fig. 4A, lane 1), whereas this
DNA pattern was not seen in the sample obtained from mock-infected
cells, even though they had been treated with 5 mM NaSal (Fig. 4A, lane
2) or aspirin (lane 6). Salicylates appeared to inhibit JEV-induced
apoptosis of infected BHK-21 cells in a dose-dependent manner, since as
the concentration of NaSal (Fig. 4A, lanes 3 to 5) or aspirin (lanes 7 to 9) increased, the extent of virus-induced DNA ladder formation
gradually decreased.
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FIG. 4.
Salicylates suppress flavivirus-induced apoptosis in
BHK-21 and N18 cells. (A) Agarose gel electrophoresis of DNA
fragmentation. BHK-21 cells were either mock infected (lanes 2 and 6)
or infected with JEV at an MOI of 5 (lanes 1, 3 to 5, and 7 to 9), and
cells were then left untreated (lane 1) or treated with NaSal (SA)
(lanes 2 to 5) or aspirin (ASA) (lanes 6 to 9) at the indicated
concentrations. Low-molecular-weight DNA was isolated from cells at
32 h postinfection and analyzed by 2% agarose gel in the presence
of EtBr. Lane M, 100-bp ladders as DNA markers. (B) Gel analysis of DNA
ladders from JEV-infected N18 cells that were left untreated (lane 1)
or treated with 5 mM SA (lane 2) at 32 h postinfection. (C)
Kinetics of DNA fragmentation from JEV-infected N18 cells that were
left untreated (filled squares) or treated (open circles) with 5 mM SA,
determined by ELISA. Prior to virus infection, cells were labeled with
BrdU overnight. At the indicated time points following infection, the
cells were permeabilized to release the cytoplasmic DNA fragments into
the supernatants. The amounts of BrdU-labeled DNA released were
measured by ELISA as optical densities (O.D.) at 450 nm using
antibodies against DNA and BrdU (see Materials and Methods).
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Similarly, 5 mM NaSal also suppressed JEV-induced apoptosis in infected
neuronal N18 cells (Fig.
4B, lane 2), whereas a DNA
ladder was observed
in infected cells without NaSal treatment
(Fig.
4B, lane 1). To further
characterize the inhibitory kinetics
of NaSal on JEV-induced apoptosis
in cell cultures, we performed
a DNA fragmentation ELISA (see Materials
and Methods) using JEV-infected
N18 cells as a model. This quantitative
analysis allowed us to
measure the amounts of free DNA fragments
released in the cytoplasm
of apoptotic cells at different time points
following infection
(
43). As shown in Fig.
4C, the amount
of DNA fragments detected
from control JEV-infected cells increased
progressively with time,
peaking at 32 h postinfection but declining
thereafter; in contrast,
when infected cells were treated with 5 mM
NaSal, the upturn in
DNA fragmentation appeared to a lesser extent, and
there was no
apparent CPE in these cells during this incubation period.
Similarly,
both NaSal and aspirin also inhibited DEN-induced apoptosis
(data
not shown). Together, these results indicate that salicylates
can
indeed diminish flavivirus-induced apoptosis in cultured cells,
likely
by blocking virus replication in the infected
cells.
The antiflavivirus effects of salicylates were not mediated by
blocking NF-B activation in infected cells.
DEN replication
activates NF-B in human hepatoma cells, which, in turn, triggers
apoptotic cell death (52). Considering that both NaSal and
aspirin have been shown to inhibit NF-B activation by preventing the
degradation of its cytoplasmic inhibitor IB (39), we
investigated whether the NF-B pathway is essential for flavivirus
replication or for the process of virus-induced apoptosis, and whether
the antiflavivirus effect of salicylates is mediated by blocking
NF-B activation in infected cells. Using an
NF-B-luciferase reporter plasmid controlled by five NF-B binding
sites (pNFB-Luc; Stratagene), we found (Fig.
5A) that after 6 h of infection, JEV
could induce NF-B activation compared to the mock infection control
(P < 0.005 by the Student t test) and
addition of 5 mM NaSal could suppress this activation (P < 0.05 by the Student t test). We next explored the
effect of an NF-B-specific cell-permeating peptide inhibitor, SN50,
on JEV replication in infected cells (48). At 1 h
post-JEVinfection, the infected BHK-21 and N18 cells were treated with
varying concentrations of SN50, and virus yields from these cells were
assessed after 36 h of incubation. The results (Fig.
6) show that neither SN50 nor its mutant
peptide (SN50M, a negative control) suppressed JEV replication in
BHK-21 (Fig. 6A) or N18 (Fig. 6B) cells, whereas the control, 5 mM
NaSal did so substantially in both types of cells. In addition, using
the NF-B-luciferase reporter system, treatment of cells with 100 µg of SN50 was found to reduce JEV-induced NF-B activation by
approximately 43% compared to untreated counterparts, whereas the
control mutant peptide, SN50M, failed to do so. On the other hand,
lactacystin, which is a specific proteasome inhibitor and is also known
as a potent inhibitor of NF-B activation (20), exhibited a negligible effect on JEV replication (Fig. 6C). In addition, neither SN50 nor lactacystin blocked the occurrence of
apoptotic cell death in JEV- or DEN-infected cells (data not shown).
However, both of these inhibitors potently repressed NF-B activation
when cells were treated with 10 nM PMA or 10 µg of poly (I · C) (data not shown), which has been shown to activate NF-B, likely
through a protein kinase C activation pathway (8, 24, 67,
76).
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FIG. 5.
Effect of NaSal or the dominant-negative mutant
IB-N on JEV-induced NF-B activation. (A) NaSal effect. A total
of 8 × 104 BHK-21 cells transfected with pNFB-Luc
were either left untreated or treated with 5 mM NaSa1 or for 18 h.
The resulting cells were then either infected with JEV (at an MOI of 5)
or mock infected, and at 6 h postinfection, cell lysates were
prepared for determination of luciferase activity. (B) IB-N
effect. A total of 8 × 104 BHK-21 cells were
transfected either with pNFB-Luc together with plB-N or with
pNFB-Luc plus the pCR3.1 vector, and these cells were then infected
with JEV at an MOI of 5 for another 6 h. The resulting cell
lysates were prepared and assessed for luciferase activity. Values
shown are representative of the results from three independent
experiments. Luciferase activity is expressed as relative light
units.
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FIG. 6.
Role of NF-B activation in JEV replication in BHK-21
and N18 cells. (A and B) Effect of the cell-permeating peptide
inhibitor SN50 on JEV replication. At 1 h postinfection,
JEV-infected BHK-21 (A) or N18 (B) cells were treated with varying
doses of SN50, and virus yields from the cells were determined by a
plaque assay after a 36-h incubation. As negative controls, the
infected cells were either left untreated (Blank) or, treated with the
mutant peptide SN50M; as a positive control, cells were treated with 5 mM NaSal (SA). (C and D) Effect of lactacystin (C) or indomethacin (D)
on JEV reproduction in BHK-21 cells. At 1 h postinfection, JEV-infected
BHK-21 cells were either left untreated (Blank) or treated with varying
doses of lactacystin or indomethacin, and after 20 h of
incubation, virus yields from the resulting cells were determined by
plaque assay as described for Fig. 1A.
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|
The effectiveness of salicylates in treating inflammation has been
attributed to their ability to inhibit prostaglandin production
by
blocking COX (
53,
74). In addition, aspirin has been
reported
to attenuate CMV replication in cultured cells, partly by
inhibiting
COX activity (
73). We therefore examined
whether suppression
of COX results in inhibition of flavivirus
replication. After
1 h postinfection, JEV-infected BHK-21 cells
were treated with
varying concentrations of indomethacin (1 to 50 µM), which is
a potent COX inhibitor with effective anti-inflammatory
function
(
34). We found that addition of indomethacin,
even at concentrations
higher than those normally used clinically had
no inhibitory effect
on JEV replication in BHK-21 cells (Fig.
6D). This
result implies
that the antiflavivirus effect of salicylates discussed
above
was not due to inhibition of COX activity in the infected
cells.
To further confirm that NF-
B activation in the infected cells was
not required for flavivirus replication or virus-induced
apoptosis, we
performed a genetic experiment using cells either
transiently or
constitutively expressing I
B
-
N, a dominant-negative
mutant
that efficiently blocks NF-
B activation (
11). The
results
in Fig.
5B show that transient expression of I
B
-
N
could efficiently
inhibit JEV-induced NF-
B activation in BHK-21
cells. We established
several independent BHK-21 clones stably
expressing I
B
-
N and
chose five of these clones (see below) to
study the replication
capability of JEV or DEN in an NF-
B-null
background. The amounts
of I
B
-
N expression in the individual
clones were found to be
similar by Western blot analysis. Using the
luciferase reporter
plasmid, we examined the status of NF-
B
activation in flavivirus-infected
cells with or without salicylate
treatments. We observed that
stable expression of I
B
-
N almost
completely suppressed constitutive
NF-
B activity compared to that in
the parental BHK-21 cells,
and such I
B
-
N-expressing clones
indeed led to failure of NF-
B
activation in response to poly(I
· C) treatment or JEV infection
(data not shown). We next examined
whether flaviviruses could
replicate in these NF-
B-null cells.
Figure
7 reveals that after
infection
with JEV (Fig.
7A) or DEN-2 (Fig.
7B), virus yields
from all five
I
B
-
N-expressing clones were similar to that from
wild-type
BHK-21 cells. In addition, we observed an apparent virus-induced
CPE,
including abnormal microscopic appearance and apoptosis indicated
by
DNA ladder formation, in flavivirus-infected, I
B
-
N-expressing
clones as readily as in infected BHK-21 cells (data not shown).
On the
other hand, NaSal or aspirin still substantially inhibited
JEV
replication (Fig.
7C) and virus-induced CPE (data not shown)
in the
I
B
-
N-expressing cells at 24 h postinfection, even though
suppression of virus yields was not as obvious as in wild-type
BHK-21
cells. Moreover, in addition to the early time point at
24 h
postinfection (Fig.
7C), we also observed the failure of
I
B-
N to
inhibit JEV replication at 36 and 54 h postinfection,
similarly,
addition of 5 mM NaSal still effectively suppressed
virus yields
approximately 100-fold in I
B-
N-expressing cells
compared to those
in their untreated counterparts. Taken together,
these results suggest
that (i) flaviviruses do not seem to require
NF-
B activation to
complete their replication, (ii) flaviviruses
do not have to activate
NF-
B in order to trigger apoptosis from
the cells we used here, and
(iii) salicylates appear to exert
antiflavivirus effects by an
NF-
B-independent mechanism in infected
BHK-21 cells.
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FIG. 7.
Effects of constitutive IB-N expression on
antiflavivirus capability of salicylates. The ability of JEV (A) or DEN
(B) to replicate in IB-N-expressing cell clones (IB#1, #8,
#12, #17, and #18) was compared to that in wild-type BHK-21 cells by
measurement of titers of virus released into the culture medium. (C)
The anti-JEV effects of salicylates were determined for the
IB-N-expressing cell clones (IB#12 and #17) and the
wild-type BHK-21 cells. After 1 h of JEV infection, cells were
left untreated or treated with 5 mM NaSal (SA) or aspirin (ASA) and
then incubated at 37°C for another 24 h. Virus production in the
culture medium was determined by a plaque assay. Data are mean virus
titers for two independent experiments.
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|
The antiflavivirus effects of salicylates were partially undermined
by blocking p38 MAPK activation.
We next investigated whether p38
MAPK might be involved in the antiflavivirus effects of salicylates.
Figure 8A shows that 5 µM SB203580,
which is a specific p38-MAPK inhibitor, partially reversed the anti-JEV
effect originating from 5 mM NaSal, while addition of SB203580 alone to
JEV-infected BHK-21 cells had no inhibitory effect on JEV replication.
Similarly, SB203580, but not its ineffective analogue SB202474, also
partly neutralized the inhibitory effect of NaSal on DEN replication in
BHK-21 cells (Fig. 8B). Together, these results suggest that the
activity of p38 MAPK may play a role in the inhibition of flavivirus
replication by salicylates in cultured cells.
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FIG. 8.
Antiflavivirus capability of salicylates in cells
treated with the p38 MAPK inhibitor SB203580. (A) BHK-21 cells were
infected by JEV at an MOI of 5, and at 1 h postinfection SB203580 (SB)
was added to the cells at varying micromolar concentrations in the
presence or absence () of 5 mM NaSal (SA). After 36 h of
incubation at 37°C, virus yields in the culture media were determined
by a plaque assay. (B) BHK-21 cells were infected by DEN at an MOI of
5, and at 1 h postinfection varying doses (micromolar
concentrations) of SB203580 or its ineffective analogue SB202474 (SBa)
were added cells in the presence or absence () of 5 mM SA. After
36 h of incubation at 37°C, virus yields in the culture media
were determined as described for Fig. 1A.
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DISCUSSION |
Aspirin and NaSal are commonly prescribed drugs that have wide
spectra of pharmacological activities and multiple sites of action. In
this study we demonstrated that aspirin and its metabolite NaSal, at
concentrations (1 to 5 mM) compatible with the amounts in the sera of
patients undergoing anti-inflammatory therapy, specifically inhibited
flavivirus replication, as well as virus-induced apoptosis, in infected
cells (Fig. 1 to 4). In contrast, salicylates had only a trivial
inhibitory effect on Sindbis virus infection under the same conditions,
despite the fact that flaviviruses and Sindbis virus, a prototype of
Alphavirus family, have several similarities, i.e., they are
both positive-sense RNA viruses that replicate primarily in the
cytoplasm of infected cells. These observations indicate that to
complete the virus life cycle, flaviviruses and Sindbis virus may
differ in their mode of replication, especially in what cellular
functions to recruit and how to exploit certain cellular factors to
form a viral replicase complex, which may or may not be functionally
influenced by salicylates. Alternatively, salicylates may be able to
directly target enzymes or structural proteins of flaviviruses more
profoundly than those of Sindbis virus. In fact, the significant
reduction in JEV NS1 proteins, but not viral envelope proteins, by
NaSal treatment (Fig. 3) suggests that the antiflavivirus effects of
salicylates may occur by direct blocking of the flavivirus replication
machinery, because NS1, which can be expressed only in infected cells,
has been shown to participate indispensably in both viral replication
and morphogenesis (49, 51, 55, 56). Aside from cellular
factors, it remains uncertain what other viral factors might also
contribute to such a salicylate-inhibitable phenotype for flavivirus
infection in a culture system.
Through a COX-2-dependent pathway, human CMV infection of smooth muscle
cells generates a large quantity of cellular reactive oxygen species
(ROS); these in turn stimulate NF-B activation, which is critical
for CMV replication (73). Aspirin and NaSal have been
demonstrated to possess anti-CMV effects, likely by directly scavenging
ROS and blocking NF-B activation; additionally, indomethacin, which,
like aspirin, is a nonselective COX-1 and COX-2 inhibitor, can
attenuate CMV infection by suppressing COX activities as well as by
reducing the amount of virus-induced ROS (73). This
observation indicates that to exert anti-CMV effects, salicylates and
indomethacin primarily intervene in the process of virus
triggering of ROS or NF-B activation in CMV-infected smooth muscle
cells. In contrast, we found that treatment of infected cells with
indomethacin failed to suppress either flavivirus replication (Fig. 6D)
or virus-induced apoptosis (data not shown), suggesting that COX
activity is not required for flavivirus infections in a culture system.
In addition, we found that the specific NF-B inhibitors SN50 and
lactacystin had no inhibitory effect on flavivirus replication
(Fig. 6A, B, and C), and even with stable expression of
dominant-negative IB-N in the host cells, flaviviruses were still capable of replicating efficiently (Fig. 7A and B) and of triggering apoptosis (data not shown). These data clearly illustrate that NF-B activation is not essential either for a flavivirus to
reproduce itself or for the infected cells to undergo apoptosis. This
result is in contrast to findings from several previous studies concerning DEN-1 (52), DEN-2 (35), Sindbis
virus (44, 46), and reovirus (18), in which
virus replication activated NF-B, which is necessary for such
viruses to induce apoptosis. This discrepancy reaffirms the notion that
whether NF-B promotes, inhibits, or plays no role in an apoptotic
process appears to depend predominantly on the specific cell type and
the type of inducer (for a review, see reference 5).
Interestingly, however, our data revealed that both aspirin and NaSal
not only diminished flavivirus production (Fig. 1) but also blocked
virus-induced apoptosis (Fig. 4), even in IB-N-expressing
cells. This finding strongly suggests that salicylates are able to
exert their antiflavivirus effects independently of blocking the
NF-B pathway in a culture system.
NaSal rapidly and persistently activates p38 MAPK, which appears to be
essential for NaSal to induce apoptosis in human fibroblasts and for
its inhibitory action on TNF-induced IB phosphorylation and
degradation (70, 71). By use of a specific p38 inhibitor, SB203580, we found that NaSal inhibited flavivirus replication, at
least in part through mediation of p38 MAPK activation, whereas SB203580 by itself failed to suppress either flavivirus reproduction (Fig. 8). To elucidate the exact role of p38 kinase in the
antiflavivirus effects of salicylates, one needs to further explore
whether activation of p38 kinase alone, in the absence of salicylate
treatment, still leads to inhibition of flaviviruses in infected cells.
Alternatively, p38 kinase activation may operate synergistically with
another known or unidentified action(s) of salicylates to inhibit
flavivirus infection. Our results shown in Fig. 8 seem to support the
latter notion, since a specific p38 inhibitor, SB203580, could only
partially attenuate the antiflavivirus effects of NaSal in infected
BHK-21 cells. However, since p38 kinases consist of p38, p38,
p38
, and p38
isoforms, and SB203580 specifically inhibits p38
and p38 (36, 42) but not p38 and p38 (19,
27, 41, 75), we cannot exclude the possibility that the
incomplete suppression by SB203580 of the antiflavivirus effects of
NaSal (Fig. 8) may have been due to failure to block the activity of
p38 and/or p38. Among the MAPK subfamilies identified in
mammalian cells, p38 kinases (30, 42, 64) are often
strongly activated by different kinds of stresses, such as UV
irradiation, osmotic shock, TNF, and interleukin 1 treatment.
Characteristically, p38 kinase activation has been suggested to play an
essential role in triggering apoptosis in several systems (10,
33, 57, 71, 78). Salicylates may conceivably be able, via p38
activation, to create a hostile cellular milieu that abrogates
flavivirus infection. It will be of interest to investigate whether the
mechanism for p38 involved in the antiflavivirus effects of salicylates
is similar to that involved in induction of apoptosis by other death stimuli.
There are other possible actions of salicylates that may contribute to
the antiflavivirus effects of salicylates and that can be confirmed by
future experiments. NaSal inhibits the activation of p42 and p44
kinases (also referred to as extracellular signal-regulated kinase
[ERK]) induced by TNF (72) and also inhibits the
activation of ERK in neutrophils for integrin-mediated responses
(63). However, by use of PD098059, a specific inhibitor of
MEK (the proximal kinase activating ERK), we found that ERK activity
may not participate in the antiflavivirus effects of salicylates (data not shown). In addition, in an activator protein-1 (AP-1)-luciferase transgenic mouse model, aspirin or NaSal suppressed UV-induced AP-1
activity in a dose-dependent manner, likely by blocking the activation
of ERK, c-Jun N-terminal kinase kinases, and p38 kinase (31). Similarly, aspirin or salicylic acid inhibited AP-1
activation, as well as tumor promoter-induced transformation, in a J6
mouse epidermal cell line; these mechanisms might involve elevation of
intracellular H+ concentrations (23). Whether
flavivirus infections activate AP-1, whether AP-1 activation is
required for flavivirus replication, and which AP-1-dependent genes may
be pharmacological targets for salicylates in the process of flavivirus
inhibition are interesting issues that remain to be studied. In
addition, NaSal treatment, which is biochemically distinguishable from
heat treatment, has been found to partially trigger a human heat shock
response (38) and induce the DNA binding state of human
heat shock transcription factor (HSF) (37). In
Drosophila melanogaster, NaSal decreases intracellular ATP
levels and induces HSF binding, as well as chromosomal puffing
(77). Thus, it can be envisioned that salicylates may utilize a heat shock pathway or deplete intracellular ATP levels to
render host cells unsuitable for infection by flaviviruses.
In summary, we found that salicylates inhibit flavivirus replication
and virus-induced apoptosis in a dose-dependent manner and that this
inhibition is apparently not mediated by blocking either COX activities
or NF-B activation. On the other hand, a specific p38 inhibitor,
SB203580, partially rescued flavivirus replication from the
antiflavivirus effects of salicylates, indicating that p38 kinase
activation by salicylates is somewhat responsible for the
antiflavivirus phenomenon. We also observed that the processes of
flavivirus replication and virus-triggered apoptosis did not appear to
require NF-B activation, at least in the cell lines used in this
study. Together, we conclude that the mechanism by which salicylates
suppress flavivirus replication, although it may involve p38 MAPK
activity, is independent of blocking the NF-B activation pathway.
However, one must exercise caution in interpreting or applying our
results concerning how salicylates inhibit DEN infections, since
salicylates are notorious for anti-platelet function, giving rise to an
increase in bleeding time, a situation that can be extremely hazardous
for a dengue hemorrhagic fever or dengue shock syndrome patient
inappropriately treated with salicylates. Nevertheless, the results of
the present study using salicylates as molecular probes in a culture
system contribute to our understanding of flavivirus-host interactions
and shed some light on the identification of potential new
pharmacological targets for the control of flavivirus infections.
| |
ACKNOWLEDGMENTS |
The kind gifts of the N18 cell line from D. E. Griffin,
pCMV4/IB-N from D. W. Ballard, and DEN-2 strain PL046
from the National Institute of Preventive Medicine are deeply appreciated.
C.-L.L. was supported by two grants (NSC 89-2320-B-016-089 and NSC
89-2323-B-016-001) from the National Science Council (NSC), ROC, and
one (DOD-89-18) from the Department of Defense (DOD), ROC. Y.-L.L.
was supported by a grant from the NSC (NSC-89-2320-B-001-018).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Immunology, National Defense Medical Center, P.O. Box 90048-505, 161 Minchuan East Rd., Sec. 6, Taipei 114, Taiwan, Republic
of China. Phone: 886-2-8792-1615. Fax: 886-2-8792-4892. E-mail:
chinglen{at}msl.hinet.net.
| |
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Journal of Virology, September 2001, p. 7828-7839, Vol. 75, No. 17
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.17.7828-7839.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
