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Journal of Virology, November 2001, p. 10170-10178, Vol. 75, No. 21
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.21.10170-10178.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Virus-Cell Interactions Regulating Induction of
Tumor Necrosis Factor Alpha Production in Macrophages Infected with
Herpes Simplex Virus
Søren R.
Paludan* and
Søren C.
Mogensen
Department of Medical Microbiology and
Immunology, University of Aarhus, Aarhus, Denmark
Received 28 March 2001/Accepted 30 July 2001
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ABSTRACT |
Macrophages respond to virus infections by rapidly secreting
proinflammatory cytokines, which play an important role in the first
line of defense. Tumor necrosis factor alpha (TNF-
) is one of the
major macrophage-produced cytokines. In this study we have
investigated the virus-cell interactions responsible for induction of
TNF- expression in herpes simplex virus (HSV)-infected macrophages.
Both HSV type 1 (HSV-1) and HSV-2 induced TNF- expression in
macrophages activated with gamma interferon (IFN-
). This induction was to some extent sensitive to UV treatment of the virus. Virus particles unable to enter the cells displayed reduced capacity to
stimulate TNF- expression but retained a significant portion which
was abolished by HSV-specific antibodies. Recombinant HSV-1 glycoprotein D was able to trigger TNF- secretion in concert with
IFN-. Sugar moieties of HSV glycoproteins have been reported to be
involved in induction of IFN- but did not contribute to TNF-
expression in macrophages. Moreover, the entry-dependent portion of the
TNF- induction was investigated with HSV-1 mutants and found to be
independent of the tegument proteins VP16 and UL13 and partly dependent
on nuclear translocation of the viral DNA. Finally, we found that
macrophages expressing an inactive mutant of the double-stranded RNA
(dsRNA)-activated protein kinase (PKR) produced less TNF- in
response to infectious HSV infection than the empty-vector control cell
line but displayed the same responsiveness to UV-inactivated virus.
These results indicate that HSV induces TNF- expression in
macrophages through mechanisms involving (i) viral glycoproteins, (ii)
early postentry events occurring prior to nuclear translocation of
viral DNA, and (iii) viral dsRNA-PKR.
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INTRODUCTION |
Herpes simplex virus (HSV) is an
enveloped DNA virus that infects through contact with mucosal
membranes. Following the initial HSV replication in epithelial cells,
the virus is transported to the ganglia where a latent infection is
established (31). A primary HSV infection is normally
associated with a vigorous host response, including production of a
range of cytokines and chemokines (26, 34, 36). Cytokines
play an important role in the immune response to HSV infections. In
particular, tumor necrosis factor alpha (TNF-), which is primarily
produced by macrophages, is known to be central for control of virus
replication (13, 27). However, TNF- and TNF--induced
products are also involved in the immunopathology often associated with
HSV infections (2, 10).
The virus-derived entities responsible for induction of TNF-
expression have been characterized for a number of viruses (reviewed in
reference 22). For instance, the virion surface proteins gp350 and gp120 of Epstein-Barr virus and human immunodeficiency virus
type 1 (HIV-1), respectively, stimulate expression of TNF- (3,
8). Apart from surface glycoproteins other viral proteins primarily with an intracellular location such as the hepatitis B virus
(HBV) protein X (HBx), the human T lymphotropic leukemia virus type 1 Tax protein and the HIV-1 Tat protein directly interact with the
intracellular signaling machinery, thus leading to TNF- expression
(7, 15). Some viruses are endowed with several components
able to stimulate production of specific cytokines. For instance, HIV-1
encodes four different proteins able to induce interleukin 6 (IL-6)
expression (3, 24, 29, 33), and the two HBV proteins HBx
and HBV core antigen both trigger expression of TNF- (15,
37). Hence, induction of a specific cytokine by virus infection
may involve several viral components. For HSV little is known about the
viral factors that bring about cytokine production. One study has
demonstrated that the glycoprotein D (gD), which is responsible for
interaction with the herpes virus entry mediators A, B, and C, is
capable of stimulating alpha interferon (IFN-) expression
(4). Others showed that infection of a permissive murine
epithelial cell line with HSV-1 triggered IL-6 secretion, which was
sensitive to UV inactivation of the virus (12). Studies from our laboratory have shown that the ability of HSV-2 to induce secretion of the IL-12/IL-23 subunit p40 in murine macrophages is also
sensitive to UV and occurs through a mechanism involving the
transcription factor nuclear factor 
B (17).
In this study we have investigated the mechanisms of TNF- induction
by HSV in macrophages. We show that HSV-1 and HSV-2 induce modest
production of TNF- in resting macrophages and strongly stimulate
TNF- production in IFN--treated macrophages. Our data suggest
that the mechanisms involved include interaction of gD with a cellular
receptor, early postentry events, and activation of the double-stranded
RNA (dsRNA)-activated protein kinase by viral RNA.
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MATERIALS AND METHODS |
Reagents.
The recombinant murine cytokines used were TNF-
(Genzyme) and IFN- (PharMingen). Recombinant HSV-1 gD and HSV-2 gG
were obtained from Viral Therapeutics and kindly provided by Sytske Welling-Wester, respectively. The antibodies used were murine monoclonal anti-gD antibody (Virusys), neutralizing polyclonal rabbit
anti-mouse TNF- antibody (Genzyme), horseradish peroxidase (HRP)-conjugated rabbit polyclonal anti-mouse immunoglobulin antibody (Transduction Laboratories), human anti-HSV antibodies (Wellcome Diagnostics), and human immunoglobulin (The Danish State Serum Institute). LumiGLO was purchased at New England BioLabs and the polyvinylidene difluoride membranes were from Novex. Other reagents used were heparin (Leo Pharmacies), N-acetylglucosamine
(Sigma), D-mannose (Sigma), G418 (Roche),
actinomycin D (Calbiochem), and PNGase (New England Biolabs).
Cell culture and virus infection.
The murine macrophage-like
cell line RAW 264.7 was maintained in Dulbecco's modified essential
medium with 1% Glutamax I (Life Technologies) supplemented with 200 IU
of penicillin per ml, 200 µg of streptomycin per ml, and 5% fetal
calf serum (FCS). For experiments the cells were seeded in either 24- or 6-well tissue culture plates at a density of 6 × 105 and 2 × 106
cells/well, respectively, and left 16 to 20 h before further treatment. RAW-pBK-CMV and RAW-PKR-M7 cells (a gift from John A. Corbett) were grown as above except that 200 µg of G418 per ml was
added. RAW-pBK-CMV and RAW-PKR-M7 cells are RAW 264.7-derived cell
lines stably transfected with pBK and the protein kinase (PKR) mutant
M7, respectively (16). Vero and 79VB4 cells were maintained in minimal essential medium supplemented with
antibiotics and FCS as above. 79VB4 cells (from Patricia G. Spear),
which is a Vero-derived cell line stably expressing gL, were further grown in the presence of 200 µg of G418 per ml. For virus
amplification, Vero and 79VB4 cells were seeded at a density of 20 × 106 cells per 175-cm2
tissue culture flask 5 h prior to infection. For plaque assays, the cells were seeded at a density of 2 × 106 cells per 22.5-cm2
tissue culture plate.
The wild-type viruses used in this study were the MS strain of HSV-2
and the HSV-1 strains HFEM, F, KOS, and 17+. gL86 (from Patricia G. Spear) is a gL mutant derived from KOS (23). The VP16
mutant in1814 and rescued virus in1814R (from
Chris M. Preston) are on a 17+ genetic back ground (1).
The temperature-sensitive mutant tsB7 is derived from HFEM
(6), and R7356 is produced from the F strain
(28). Both viruses were kindly donated by Bernard Roizman.
The virus and mock preparations were produced as previously described
(9). The virus infectivity titers were determined by
plaque assay in Vero cells. For gL86, virus was quantified by Western
blotting using a mouse monoclonal anti-gD antibody for detection. Just
before usage, virus was thawed and used as infectious virus, subjected
to heat inactivation at 56°C for 30 min, or inactivated by UV light
for 20 min. For formaldehyde inactivation, virus was incubated 24 h at 4°C with 3.5% formaldehyde or phosphate-buffered saline (PBS)
control before being added to the cells. To deglycosylate the virus,
3 × 106 PFU of virus in PBS were incubated
with 1,000 U of PNGase at 37°C for 3 h.
Plaque assay.
Vero cells were seeded and left overnight to
settle. Infection was performed by incubating the cells with 100 µl
of 10-fold virus dilutions plus 400 µl of medium. The tissue culture
dishes were rocked every 15 min to ensure even distribution of the
virus. After 1 h, 8 ml of preheated minimal essential medium
supplemented with 2% FCS and 0.02% human immunoglobulin was added,
and the cells were incubated for 2 to 6 days, depending on the virus
strain. The cells were stained with 0.03% methylene blue, and the
numbers of plaques were determined.
Experimental procedures.
For examination of TNF-
production, RAW 264.7 cells were seeded at a density of 6 × 105 cells in 2-cm2 wells in
a volume of 1 ml and left overnight to settle. The cells were treated
with 100 IU of IFN- per ml and infected with 3 × 105 PFU of HSV per ml or an equivalent amount of
mock virus preparation and incubated at 37°C. Supernatants were
harvested after the appropriate period of incubation (as indicated in
the individual experiments). Prior to measurement of TNF-,
infectious virus in the supernatants were inactivated by UV irradiation
for 20 min. TNF- activity was measured by a bioassay (see below). To
test the influences of heparin, anti-HSV antibodies,
D-mannose, and N-acetylglycosamine on the
ability of HSV to induce TNF- expression, the substances were given
to the cells immediately prior to addition of virus to the cultures.
Formaldehyde-inactivated virus was diluted 300 times to reach a final
concentration equivalent to 3 ×105 PFU of virus
per ml in the cell cultures. This led to a final formaldehyde
concentration of 0.01%, which did not cause any overt toxic effects on
the cells.
TNF- bioassay.
Measurement of TNF- bioactivity was
performed with the L929 cell-based bioassay. L929 cells were seeded
(2 × 104 cells/well in 96-well culture
plates) and left for 16 to 24 h at 37°C in a humidified
atmosphere with 5% CO2. The culture supernatants were removed and substituted with the samples to be assayed for TNF-
content in successive twofold dilutions and incubated at 38.5°C with
1 µg of actinomycin D per ml for 18 h. Cells were fixed in 10%
formaldehyde and stained with crystal violet (1 mg/ml). Measurement of
light absorbance at 580 nm and comparison with a TNF- standard
dilution series allowed assessment of TNF- activity. The bioassay
was specific for TNF- since the activity was neutralized with a
neutralizing antibody against TNF-.
Western blotting.
Virus particles and recombinant proteins
were denatured in sample buffer (140 mM Tris-HCl [pH 8.5], 10%
glycerol, 2% sodium dodecyl sulfate [SDS], 1 mM EDTA, 0.019% Serva
Blue G250, 0.06% phenol red) and subjected to SDS-polyacrylamide gel
electrophoresis (PAGE) followed by blotting onto a polyvinylidene
difluoride membrane and blocking for 1 h in Tris-buffered saline
(10 mM Tris, 140 mM NaCl) supplemented with 0.05% Tween 20 and 5%
skim milk powder. The anti-gD antibody was added for overnight
incubation at 4°C. The membrane was washed 4 × 10 min in
washing buffer (Tris-buffered saline plus 0.05% Tween 20) and
incubated for 1 h at room temperature with a polyclonal
HRP-conjugated antibody against mouse immunoglobulin. The membrane was
washed as above and the HRP-conjugated antibody was visualized using
enhanced chemiluminescence.
Statistical analysis.
The data shown are means ± standard errors of the means. Statistical significance was estimated
with Student's t test for unpaired observations. TNF-
concentrations from repeated experiments were pooled and used for the
calculations in order to obtain the largest number of observations
available for evaluation of statistical significance. P
values of <0.05 were considered significant.
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RESULTS |
HSV-1 and HSV-2 induce secretion of TNF- in
IFN--treated macrophages.
We have previously shown that HSV-2
infection of macrophages induces secretion of TNF- (9)
and that IFN- synergistically enhances the response
(26). The data in Fig. 1A
confirm these findings and show that TNF- production is detectable
in the culture supernatants of the macrophage-like cell line RAW 264.7 already 2 h after infection and reaches a maximum after 8 h.
Mock infection did not induce appreciable amounts of TNF- in resting
or IFN--treated macrophages (data not shown). HSV-1 was also able to
induce TNF- expression in macrophages through cooperation with
IFN- (Fig. 1B). Moreover, by using three HSV-1 strains with
different degrees of virulence (HFEM < KOS < 17+) we found
that the capacity to induce TNF- did not correlate with virus
virulence (Fig. 1C).
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FIG. 1.
TNF- production in resting and IFN--treated
macrophages infected with infectious and UV-inactivated HSV. (A) RAW
264.7 cells were treated with 100 IU of IFN- per ml and infected
with 3 × 105 PFU (multiplicity of infection [MOI],
0.6) of HSV-2 per ml. After the indicated time points posttreatment,
supernatants were harvested and analyzed for TNF- bioactivity.  ,
IFN-;  , HSV-2;  , IFN- + HSV-2. (B) RAW 264.7 cells were
treated with 100 IU of IFN- per ml and infected with the following
amounts of HSV-1 (KOS): 3 × 103 PFU/ml (MOI, 0.006),
3 × 104 PFU/ml (MOI, 0.06), 3 × 105
PFU/ml (MOI, 0.6), and 3 × 106 PFU/ml (MOI, 6). (C)
RAW 264.7 cells were treated with 100 IU of IFN- per ml and 3 × 105 PFU (MOI, 0.6) of the three HSV-1 strains HFEM, KOS,
and 17+ per ml. (D) RAW 264.7 cells were treated with 100 IU of IFN-
per ml and infected with 3 × 105 PFU (MOI, 0.6) of
HSV-2 (black bars) or an equivalent amount of UV-inactivated virus
(hatched bars) per ml. For panels B, C and D, supernatants were
harvested 8 h postinfection and analyzed for TNF- bioactivity.
Results are shown as means of two cultures ± standard errors of
the means. Similar results were obtained in at least three independent
experiments.
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In separate experiments it has been observed that treatment of
RAW 264.7 macrophages with HSV-2 does lead to viral entry and
cellular
accumulation of immediate-early, early, and late transcripts
and
proteins (J. Melchjorsen and S. R. Paludan, unpublished
data).
To assess the requirement for a functional viral genome in
TNF-
induction, we tested the ability of UV-irradiated virus to
induce
TNF-
secretion. The results show that although such treatment
significantly reduced the TNF-
-inducing capacity of the virus,
UV
irradiation was unable to abolish HSV-2-induced TNF-
production
(Fig.
1D). In experiments not presented here we further found
that
induction of TNF-
by UV-inactivated virus followed the same
kinetics
as infectious HSV-2. Similar results were obtained in
murine peritoneal
cells with both HSV-1 and HSV-2 (data not shown).
The remaining
potential to bring about TNF-
secretion was not
due to incomplete
inactivation of the virus since UV-treated virus
was unable to induce
immediate-early viral gene transcription
and to replicate in Vero cells
(data not
shown).
Inhibition of viral entry reduces
but does not abolishthe
ability of HSV to induce TNF- secretion.
The initial step in
HSV infections is the interaction between the viral glycoprotein gC and
heparan sulfates on the cell surface. Consistently, free heparin has
been shown to prevent viral entry presumably by engaging gC molecules
on the virus particle (11). In agreement with this we
observed that the presence of 100 µg of heparin per ml in the growth
medium totally prevented 3 × 105 PFU of
HSV-2 from forming plaques in Vero cells (Fig.
2A). Thus, in the presence of saturating
amounts of heparin, the interaction between gC and heparan sulfates
cannot occur while other viral glycoproteins may still interact with
cellular surface proteins. At the level of TNF- production we found
that although heparin reduced the ability of HSV-2 to induce TNF-
secretion by more than 70%, a significant proportion of the
TNF--inducing potential was retained (Fig. 2C). As in the absence of
heparin, a strong synergy between the virus and IFN- was observed.
The remaining TNF--inducing potential of the virus could not be
ascribed to nonspecific effects since it was totally inhibited by
anti-HSV antibodies. In contrast to TNF-, induction of interleukin
12 (IL-12) p40 and IL-6 by HSV-2 was fully inhibited by heparin (data not shown).
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FIG. 2.
Effects of heparin and formaldehyde inactivation on
viral replication and TNF- production. (A) Confluent Vero cells were
infected with increasing amounts of HSV-2 (1 × 101,
3 × 102, 1 × 104, and 3 × 105 PFU) in the presence and absence of 100 µg of heparin
per ml. After 48 h of infection, the cells were stained and
plaques were counted. (B) HSV-2 was inactivated by incubation with
3.5% formaldehyde for 24 h at 4°C or, as a control, treated
with PBS. The virus was titrated on confluent Vero cells. After 48 h of infection, the cells were stained and plaques were counted. (C)
RAW 264.7 cells were treated with 100 IU of IFN- per ml and infected
with 3 × 105 PFU (MOI, 0.6) of HSV-2 per ml in the
presence and absence of 100 µg of heparin per ml. (D) RAW 264.7 cells
were treated with 100 IU of IFN- per ml and infected with 3 × 105 PFU (MOI, 0.6) of HSV-2 per ml or equal amounts of
formaldehyde-inactivated virus. Supernatants were harvested 8 h
later and analyzed for TNF- bioactivity. Results are shown as means
of two cultures ± standard errors of the means. Similar results
were obtained in two independent experiments.
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We also examined the TNF-
-inducing potential of formaldehyde-treated
virus, which can bind to but not fuse with the cellular
membrane.
Although formaldehyde treatment completely inactivated
the virus, as
assessed by replication in Vero cells (Fig.
2B),
it did not entirely
prevent TNF-
production (Fig.
2D). Approximately
30% of the full
TNF-
-inducing capacity was conserved, and this
portion could be
inhibited if the cells treated with the inactivated
virus also received
anti-HSV
antibodies.
To analyze the requirement for viral entry in TNF-
induction more
thoroughly, we used an HSV-1 mutant lacking the glycoprotein
gL. This
HSV glycoprotein, which forms heterodimers with gH, is
essential for
fusion of the virus envelope with the cellular membrane
(
30,
35). Thus, HSV particles deficient in gL are able to
interact
with cellular-surface heparan sulfates and proteins and
to adhere to
the cells but fail to fuse with the cellular membrane
(
32). We confirmed these previous observations using Vero
cells
(Fig.
3A). As to the ability of
these viruses to influence TNF-
expression in RAW 264.7 cells, we
found that gL86 virus grown
in Vero cells (gL86/Vero), and hence
lacking gL, displayed reduced
ability to induce TNF-
production
(Fig.
3B) compared to the virus
grown in gL-expressing Vero cells
(gL86/79VB4). However, and in
parallel with the results shown in Fig.
2, inhibition of entry
did not totally abolish TNF-
production. The
presence of anti-HSV
antibodies completely abolished induction of
TNF-
by gL86/Vero.
Collectively these results show that viral entry
is not required
for induction of TNF-
secretion by macrophages but
also demonstrate
that postentry events are required for maximal TNF-
production.
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FIG. 3.
Replication and induction of TNF- expression by
gL-deficient HSV-1. (A) Confluent 79VB4 and Vero cells were infected
with increasing amounts of gL-rescued gL86 (gL86/79VB4) and gL86
(gL86/Vero), respectively. After 48 h of infection, the cells were
stained and plaques were counted. Antigen levels of the two virus
preparations were compared by Western blotting using a specific
gD-directed monoclonal antibody. (B) RAW 264.7 cells were treated with
100 IU of IFN- per ml and infected with 3 × 105
PFU (MOI, 0.6) of gL86/79VB4 or equivalent amounts of gL86/Vero per ml.
Supernatants were harvested 8 h later and analyzed for TNF-
bioactivity. Results are shown as means of duplicate cultures ± standard errors of the means. Similar results were obtained in three
independent experiments.
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Recombinant gD induces TNF- secretion in macrophages.
It
has previously been shown that HSV-1 gD is able to trigger secretion of
IFN- (4), and signaling cellular receptors for gD are
known (18, 23). Given the observation that HSV-1 and HSV-2
can induce TNF- production independent of entry, we wanted to
investigate how gD influenced TNF- production. To test this, RAW
264.7 cells were cultured in the presence and absence of IFN- and
recombinant gD and supernatants were assayed for TNF- bioactivity.
As seen in Fig. 4A, gD treatment alone
led to a modest increase in TNF- levels but significantly induced TNF- secretion if given together with IFN-. Three hundred
nanograms per ml of gD was sufficient to stimulate TNF- production
in IFN--treated cells, and maximal levels of TNF- were reached
with around 3 µg of gD per ml (Fig. 4B). Another HSV glycoprotein,
gG-2, did not trigger TNF- production in RAW 264.7 macrophage-like
cells. When examining the ability of recombinant gD to induce TNF-
production in peritoneal macrophages, we observed that these cells
responded to the glycoprotein in a manner similar to that of RAW 264.7 cells (data not shown).
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FIG. 4.
Induction of TNF- production in RAW 264.7 cells by
recombinant gD-1. The cells were treated with 100 IU of IFN- per ml
and either 3 µg/ml of recombinant gD-1 (A) or concentrations of gD-1
and gG-2 ranging from 0.1 to 10 µg/ml (B). Supernatants were
harvested 8 h later and analyzed for TNF- bioactivity. Results
are shown as means of duplicate cultures ± standard errors of the
means. Symbols: , untreated; , IFN- + gD-1;  IFN- + gG-2;  IFN- + gD-1 + -HSV antibody. (C) Semiquantification of
gD on 3 × 105 PFU of HSV-1. Virus was loaded onto an
SDS-PAGE together with increasing amounts of recombinant gD and
subjected to Western blotting using a monoclonal antibody against gD.
The level of gD in the sample was estimated by comparison with the
recombinant gD standard. Similar results were obtained in two
independent experiments.
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To assess if the levels of recombinant gD required to induce TNF-
secretion corresponded to the quantity present on 3 × 10
5 PFU of HSV-1, this amount of virus was loaded
onto an SDS-PAGE
together with known amounts of recombinant gD and
subjected to
Western blotting. We found that whereas recombinant gD was
present
in both unglycosylated and various glycosylated forms, the gD
in the virus particle appeared to be uniformly glycosylated as
assessed
from the mobility in the gel. Moreover, the experiment
shows that
3 × 10
5 PFU of HSV-1 contain approximately
0.5 µg of gD (Fig.
4C) and
thus shows that the amounts of recombinant
gD capable of inducing
TNF-
are comparable to the levels present on
3 × 10
5 PFU of HSV-1.
Induction of TNF- by HSV is independent of glycosylation of the
virus
Since previous work from other laboratories
has shown that HSV-1-induced IFN- expression by dendritic cells is
inhibited by the presence of free sugars in the growth medium and by
neutralizing antibodies against the mannose receptor (20),
we wanted to investigate if sugar moieties also were involved in
stimulation of TNF- production in macrophages. When 50 mM
D-mannose was present in the growth medium we did observe
significant reduction of TNF- production (Fig.
5D) (P = 0.003),
whereas the same amount of N-acetylglucosamine did not
affect the induction of TNF- by HSV (Fig. 5E). The free sugars did
not affect viral replication (Fig. 5A and B).
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FIG. 5.
Effect of virus glycosylation on TNF- induction. (A
and B) Confluent Vero cells were infected with increasing amounts of
HSV-2 (1 × 101, 3 × 102, 1 × 104, and 3 × 105 PFU) in the presence and
absence of 50 mM D-mannose (A) or
N-acetylglucosamine (B). (C) HSV-2 was treated with
1,000 U of PNGase or PBS at 37°C for 3 h prior to infection in
the same doses as above. After 48 h of infection, the cells were
stained and plaques were counted. (D to F) RAW 264.7 cells were treated
with 100 IU of IFN- per ml and 3 × 105 PFU
(multiplicity of infection, 0.6) of HSV-2 per ml. The growth medium was
supplemented with free sugars (50 mM D-mannose [D] or
N-acetylglucosamine [E]) or the virus was
deglycosylated with PNGase prior to infection (F). After 8 h of
infection, supernatants were harvested and analyzed for TNF-
bioactivity. Results are shown as means of duplicate cultures ± standard errors of the means. Similar results were obtained in three
independent experiments. *, P < 0.05.
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However, since mannose (at least in the doses used in our study) was
mildly toxic to the RAW 264.7 cells, we also assessed
the involvement
of glycoprotein sugar moieties in TNF-
induction
by stripping the
virus for sugars prior to infection. Incubation
of the virus with
PNGase for 3 h increased the mobility of gD
on SDS-PAGE, showing
that the treatment did deglycosylate the
virus (data not shown).
However, the infectivity was unaltered,
as was the TNF-
-inducing
potential (Fig.
5C and F). These results
indicate that HSV infection of
macrophages induces TNF-
expression
independently of the
glycosylation status of the
virus.
Induction of TNF- is independent of the transactivating
potential of VP16 and the viral protein kinase UL13 and partly
dependent on nuclear translocation of the HSV
genome
Since full induction of TNF- secretion
requires viral entry we wanted to investigate whether the
virion-associated transcription factor VP16, either directly or
indirectly via stimulation of immediate-early gene expression, was
involved in activation of TNF- expression. For this purpose we used
the VP16 mutant in1814, which is unable to associate
with cellular transcriptional coactivators (1). When RAW
264.7 cells were infected with this virus or the VP16-rescued virus
(in1814R) we found an unaltered ability to induce
TNF- (Fig. 6A). In fact, we observed
that although in1814R was severalfold more infectious
than in1814, the TNF--inducing capacity correlated
with virus quantity (gD levels) rather than the plaque-forming
potential (data not shown). Likewise, when examining the ability of the
UL13 mutant R7356 to induce TNF-, we also found no defect relative
to the wild-type virus F (Fig. 6B).
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FIG. 6.
Induction of TNF- secretion in RAW 264.7 cells by
HSV-1 mutants with defects in VP16 and UL13 or nuclear translocation of
viral DNA. (A) Cells were treated with 100 IU of IFN- per ml and
infected with 3 × 105 PFU (multiplicity of infection
[MOI], 0.6) of in1814 or the rescued virus
in1814R per ml. (B) The cells were treated with IFN-
as above and infected with 3 × 105 PFU (MOI, 0.6) of
R7356 or wild-type F strain per ml. (C) Cells preheated to 39.5°C
were treated with 100 IU of IFN- per ml and infected with 3 × 105 PFU (MOI, 0.6) of tsB7 or wild-type HFEM
per ml. The cells were further incubated at 39.5°C. (A to C) After
8 h of infection, supernatants were harvested and analyzed for
TNF- bioactivity. Results are shown as means of duplicate
cultures ± standard errors of the means. Similar results were
obtained in three independent experiments. *, P < 0.05.
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To further characterize the part of the TNF-
-inducing signal that
was dependent on viral entry, we used the HSV-1 mutant
tsB7,
which is unable to release DNA into the nucleus at 39.5°C
(
6). This allowed us to dissect the involvement of
specific
events occurring after viral entry. We found that wild-type
HFEM
was capable of inducing TNF-
expression at 39.5°C (Fig.
6C).
Interestingly, although the
tsB7 mutant also induced TNF-
expression,
this occurred at significantly lower levels than those
observed
for the wild-type virus (
P = 0.001). At 37°C
the abilities of
the two viruses to induce TNF-
expression were
indistinguishable
(data not shown). Thus, VP16 and UL13 are not central
players
in HSV-induced TNF-
secretion in macrophages, which involves
virus-cell interactions occurring both before and after translocation
of the viral genome to the
nucleus.
The dsRNA-activated protein kinase PKR participates in TNF-
expression in HSV-infected macrophages.
Given the partial
sensitivity of TNF- induction by HSV to UV irradiation of the virus
we wanted to investigate if the dsRNA-activated protein kinase (PKR)
played a role in TNF- induction by HSV. Since accumulation of viral
mRNA during virus replication is sensitive to UV irradiation and PKR is
a potent stimulator of proinflammatory signaling, we speculated that
this kinase could potentially contribute to the cellular signaling
machinery leading to TNF- expression. To test this we used a
previously described RAW-derived cell line (16)
overexpressing a PKR mutant (M7) lacking the first RNA-binding domain
of the protein. As a control we used a cell line (RAW-pBK-CMW) stably
transfected with the empty pBK vector. This cell line responded to
HSV-1 and HSV-2 infection alone with a remarkably high production of
TNF-, which was enhanced by cotreatment with IFN- (Fig.
7A and data not shown). RAW-PKR-M7 was
also capable of producing TNF- after HSV-1 and HSV-2 infection but
at significantly lower levels (P = 0.01).
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|
FIG. 7.
Effects of PKR inactivation on TNF- induction by HSV.
(A) RAW-pBK-CMV and RAW-PKR-M7 cells were treated with 100 IU of
IFN- per ml and infected with 3 × 105 PFU
(multiplicity of infection [MOI], 0.6) of HSV-2 per ml as indicated.
(B) The cells were treated as for panel A with the sole modification
that the virus was UV irradiated prior to addition to the cell
cultures. (C) RAW-PKR-M7 cells were treated with 100 IU of IFN- per
ml and 3 × 105 PFU (MOI, 0.6) of gL86/79VB4 per ml or
equivalent amounts of gL86/Vero. (A to C) After 8 h of infection
the levels of bioactive TNF- in the supernatants were assayed.
Results are shown as means of duplicate cultures ± standard
errors of the means. Similar results were obtained in three independent
experiments. *, P < 0.05.
|
|
To assess if the role of PKR was dependent on viral dsRNA we tested how
the cell lines responded to UV-inactivated virus.
Interestingly, unlike
what was observed after treatment of the
cells with infectious virus,
UV-inactivated virus resulted in
comparable levels of TNF-
production in the two cell lines (Fig.
7B). Finally, we wanted to
examine if in fact postentry events
other than PKR contributed to
TNF-
production. To do this we
used the PKR mutant cell line used in
experiments illustrated
in Fig.
7A and B and the above-described
viruses gL86/Vero and
gL86/79VB4 (Fig.
3). As seen from Fig.
7C,
gL86/79VB4 remained
a significantly more potent inducer of TNF-
than
was gL86/Vero
(
P = 0.006) despite lack of a functional
PKR system in the RAW-PKR-M7
cell line. Thus, these results suggest
that signaling through
viral dsRNA-activated PKR plays a role in
HSV-induced TNF-
expression
in macrophages and that entry-dependent
events other than PKR
are
involved.
| |
DISCUSSION |
Production of cytokines is an essential part of the early response
to viral infection. This induces an antiviral state in infected cells
and recruits cells of the immune system to the site of infection.
Macrophages play an essential role in the natural immune response to
many viruses and among these HSV (13, 21). One of the
macrophage-derived products that contribute to inhibition of HSV
replication is the cytokine TNF- (13, 27), which
induces a number of antiviral effector mechanisms, notably production of nitric oxide (5, 26). In this study we have
investigated the virus-cell interactions that trigger production of
TNF- in murine macrophages.
The ability of HSV infection to stimulate TNF- expression to any
major extent in RAW 264.7 macrophage-like cells was dependent on the
presence of IFN-. Similar findings have previously been done in
another murine macrophage-like cell line (J774A.1) and in murine
peritoneal cells (26). Since IFN- is known to be produced early during HSV infections by NK cells (19, 25), this observation emphasizes the importance of interplay between different cells of the immune system in order to bring about a robust
host response.
For some viruses it has been shown that more than one mechanism is
involved in cytokine induction. HBV is able to stimulate TNF-
production through both HBx and the HBV core antigen (15, 37). Likewise, several HIV-1 proteins promote IL-6 expression (3, 24, 29, 33). We found that the ability of HSV to induce TNF- expression is dependent on entry-independent events and
at least two different postentry events: one independent of release of
viral DNA into the nucleus and one dependent on PKR and a functional
viral genome. These results are compatible with the model shown in Fig.
8.
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|
FIG. 8.
Model for virus-cell interactions in induction of
TNF- production by HSV. First, interaction between gD and a cellular
receptor triggers intracellular signals leading to production of low
levels of TNF-. Second, viral entry also stimulates signaling
pathways with a positive effect on TNF- gene expression. The nature
of the viral component or activity responsible for this signal
is not known but could involve membrane fusion, viral tegument
proteins, or changes in the cytoskeleton. Third, accumulation of viral
dsRNA and subsequent activation of PKR also promotes TNF-
production. IFN-, which strongly enhances HSV-induced TNF-
expression, is omitted from the figure.
|
|
The entry-independent TNF- induction could be mimicked by
recombinant gD. It is possible that the viral glycoprotein interacts with one of the cellular herpes virus entry mediators, which in turn
mediates intracellular signaling. In this respect it is interesting that the herpesvirus entry mediator A is a member of the TNF receptor superfamily and is known to activate some of the transcription factors
involved in regulation of TNF- transcription (18). However, it is also possible that gD induces TNF- expression through
binding to receptors other than the entry mediators. In fact, it has
been reported that the ability of gD to stimulate IFN- secretion can
be inhibited with antibodies directed against the chemokine receptors
CCR3 and CXCR4 (4). The concept of immune stimulation by
viral surface proteins is well described in the literature. To
illustrate, gp350 of Epstein-Barr virus and gp120 of HIV-1 stimulate
expression of TNF- (3, 8), and it was recently reported
that the fusion protein of respiratory syncytial virus is recognized by
toll-like receptor 4 and CD14 (14).
Concerning the postentry events involved in TNF- induction, we found
that both UV-sensitive and -insensitive mechanisms are involved. The
existence of the entry-dependent UV-insensitive response was documented
primarily by the observations (i) that the gL-deficient virus particles
(gL86/Vero) induced lower levels of TNF- than did the gL-containing
virions (gL86/79VB7) in RAW-PKR-M7 cells, which lack dsRNA-responsive
PKR; (ii) that UV-irradiated virus induced comparable amounts of
TNF- in RAW-PKR-M7 and RAW-pBK-CMV cells; and (iii) that
tsB7 was a less potent inducer of TNF- than HFEM at the
nonpermissive temperature, under which condition the mutant is unable
to release its DNA into the nuclei of infected cells. The exact nature
of the virus-cell interaction responsible for this response is not
known but is independent of VP16 and UL13. Potential candidates include
fusion of the viral envelope with the cell membrane, tegument proteins
other than VP16 and UL13, changes in the cytoskeleton caused by
transport of the capsid to the nuclear pores, or sensing by the cell of
HSV capsids.
The entry-dependent signal sensitive to UV irradiation of virus
involved PKR. This conclusion is based on the finding that the PKR
mutant cell line RAW-PKR-M7 produced lower amounts of TNF- than did
the control cell line RAW-pBK-CMV in response to infectious virus but
similar levels after treatment with UV-inactivated virus. Since PKR is
activated by dsRNA (38) and UV irradiation of virus
inhibits transcription from the viral genome, these results suggest
that this signal is comprised of PKR activated by HSV mRNA produced
during the viral life cycle.
In summary, we have shown that the HSV glycoprotein gD is able to
induce secretion of TNF- in macrophages and that postentry events
are required for full induction. Our results suggest that macrophages
can react to HSV with three levels of TNF- secretion: (a) a low
response that is induced when the macrophage detects the virus on the
cell surface, (b) a stronger response that is initiated when the virus
has entered the cell, and (c) full induction when the infecting virus
goes through its replication cycle.
| |
ACKNOWLEDGMENTS |
We thank Patricia G. Spear for the gL86 HSV-1 mutant and the
79VB4 cell line, Chris M. Preston for the viruses in1814
and in1814R, and Bernard Roizman for the mutant viruses
tsB7 and R7356. We are also indebted to Sytske
Welling-Wester for providing the recombinant HSV-2 gG. The generous
donation of the cell lines RAW-pBK-CMV and RAW-PKR-M7 by John A. Corbett is greatly appreciated. The skillful technical help provided by
Birthe Søby and Elin Jakobsen has been invaluable.
This work was supported by grants from the Danish Health Science
Research Council (grant number 12-1622), Fonden til Lægevidenskabens Fremme (grant number 00182), and The Leo Research Foundation.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Medical Microbiology and Immunology, The Bartholin Building, University of Aarhus, DK-8000 Aarhus C, Denmark. Phone: (45) 8942 1767. Fax: (45)
8619 6128. E-mail: srp{at}microbiology.au.dk.
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Journal of Virology, November 2001, p. 10170-10178, Vol. 75, No. 21
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.21.10170-10178.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Top
Abstract
Introduction
