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Journal of Virology, March 1999, p. 2173-2180, Vol. 73, No. 3
Departamento de Sanidad Animal,
Received 30 July 1998/Accepted 2 December 1998
We have analyzed the production of tumor necrosis factor alpha
(TNF- African swine fever (ASF) virus
(ASFV) is a large, icosahedral DNA virus currently considered the only
member of a new family of animal viruses (38). ASFV infects
soft ticks of the genus Ornithodoros and different members
of the Suidae family. In the natural swine hosts, the
warthog and bushpig, ASFV causes inapparent or mild infections with few
clinical signs. In contrast, infection of the domestic pig by virulent
isolates results in a devastating disease with high mortality
(11).
Acute ASF is characterized by disseminated intravascular coagulation
with multiple hemorrhages in all tissues, leading to animal death
within a few days, as a consequence of shock (37). ASFV
replicates mainly in macrophages and monocytes (22, 39), and
its ability to infect these cells has been considered to play a
critical role in the pathogenicity of the disease (11). It has been demonstrated that, upon in vitro and in vivo infection with
ASFV, apoptosis is induced in target cells (31). Moreover, infected animals present marked leukopenia and severe impairment of
lymphoid organs, characterized by lymphocyte apoptosis and significant
cellular depletion mainly affecting the spleen and lymph nodes
(17, 32). Considering the nonsusceptibility of lymphocytes
to ASFV infection, the effects observed in this population are most
likely due to soluble mediators released by infected cells.
Monocytes-macrophages secrete a large range of soluble mediators,
including proinflammatory cytokines such as interleukin-1 (IL-1), IL-6,
and tumor necrosis factor alpha (TNF- The aim of this study was to analyze the expression pattern of TNF- Virus, cells, and in vitro infections.
The virulent E-75
strain of ASFV was grown in buffy coat cell cultures as previously
described (33). Virus was titrated in swine peripheral blood
mononuclear cells (PBMC) and expressed as 50% tissue culture-infective
doses per milliliter (18). When required, virus inactivation
was performed by irradiation with UV light at a distance of 15 cm for
10 min by using a G15T8 UV lamp (15 W; Philips, Eindhoven, The
Netherlands). Lack of infectivity of UV-treated virus was confirmed by
the absence of a cytophatic effect on macrophage cultures 10 days after
inoculation and by the absence of ASFV p73 expression by immunofluorescence.
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
African Swine Fever Virus Infection Induces Tumor
Necrosis Factor Alpha Production: Implications in
Pathogenesis
ABSTRACT
Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
) induced by in vitro infection with African swine fever (ASF)
virus (ASFV) and the systemic and local release of this inflammatory
cytokine upon in vivo infection. An early increase in TNF- mRNA
expression was detected in ASFV-infected alveolar macrophages, and high
levels of TNF- protein were detected by ELISA in culture
supernatants from these cells. When animals were experimentally
infected with a virulent isolate (E-75), enhanced TNF- expression in
mainly affected organs correlated with viral protein expression.
Finally, elevated levels of TNF- were detected in serum,
corresponding to the onset of clinical signs. TNF- has been reported
to be critically involved in the pathogenesis of major clinical events
in ASF, such as intravascular coagulation, tissue injury, apoptosis,
and shock. In the present study, TNF- containing supernatants from
ASFV-infected cultures induced apoptosis in uninfected lymphocytes;
this effect was partially abrogated by preincubation with an
anti-TNF- specific antibody. These results suggest a relevant role
for TNF- in the pathogenesis of ASF.
INTRODUCTION
Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
) (35). Among them,
TNF- may particularly contribute to the pathogenesis of ASF
(27). TNF- induces vasodilation, an increase in vascular permeability, and activation of the vascular endothelium, all of which
alter the balance between procoagulant and anticoagulant activities and
favor the generation of microthrombi (6, 23). Furthermore,
TNF- provides signals involved in the cellular control of programmed
cell death (25, 40). Elevated systemic levels of TNF-
result in disseminated intravascular coagulation (with consumption of
clotting factors), leading to extensive hemorrages, shock, multiple
organ failure, and death (36).
following ASFV infection. We evaluated TNF- production by
macrophages induced by in vitro infection and increased levels of
TNF- in the sera and organs of animals experimentally infected with
a virulent ASFV isolate (E-75). Altogether, our findings suggest the
involvement of TNF- in the pathogenesis of ASF.
MATERIALS AND METHODS
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Abstract
Introduction
Materials and methods
Results
Discussion
References
Animal infection procedures. Three-month-old Large-White pigs (six for each experiment) were intramuscularly inoculated in the shoulder with 105 50% tissue culture-infective doses of the E-75 isolate. One inoculated pig was killed daily for pathological examination and collection of blood and tissue samples. Clinical symptoms and temperature were recorded. In addition, blood samples were collected daily from one of two additional inoculated animals. Two pigs injected with a saline solution were used as controls. Animals were sedated with azaperone (Stresnil; Esteve) and euthanized with pentobarbital (Doletal; Vetoquine).
Cytokines and antibodies.
Recombinant bovine (rBo) TNF-
was kindly supplied by Rolf Steiger of Ciba-Geigy Ltd. (Basel,
Switzerland) and had a specific activity of 1.5 × 106
U/mg (lot no. 4447-95, code CGA 214 666). Bovine and porcine TNF-
proteins show 84% homology (5). Recombinant porcine TNF- (specific activity, 108 U/mg) and antiporcine TNF-
monoclonal antibody (MAb) 4F4 were purchased from Endogen.
emulsified in complete Freund's adjuvant. At monthly intervals, they received subcutaneous booster injections (20 µg per
dose) of rBo TNF- in incomplete Freund's adjuvant, and blood was
periodically collected. Serum immunoglobulin G was purified by affinity
chromatography with protein A-Sepharose CL4B (Pharmacia, Uppsala,
Sweden) and biotin labeled as described elsewhere (12).
RT-PCR analysis of TNF- mRNA expression.
Total RNA was
isolated by using the Tripure Isolation reagent (Boehringer Mannheim,
Indianapolis, Ind.) by a method based on that described by Chomczynski
and Sacchi (10). First-strand cDNA was obtained from 5 µg
of total RNA (previously denatured by heating for 2 min at 65°C and
immediately placed on ice) with 5 µl of a reverse transcriptase (RT)
reaction mixture containing 10× Moloney murine leukemia virus RT
buffer (Epicentre), 10 mM dithiothreitol, 0.5 mM oligo(dT), 50 µM
each deoxynucleoside triphosphate, 12.5 U of Moloney murine leukemia
virus RT (Epicentre), and 20 U of RNasin (Promega). The reaction
mixtures, at a final volume of 50 µl with RNase-free water, were
incubated for 1 h at 37°C. For PCR, a variable amount of the
cDNA (typically, 2.5 µl) was used in a total volume of 25 µl of a
PCR mixture containing 10 mM Tris-HCl (pH 8.3), 50 mM KCl, 0.005%
Tween 20, 0.005% Nonidet P-40, 0.5 to 1 mM MgCl2
(depending on the oligonucleotide pair), 50 µM each deoxynucleoside
triphosphate, 10 pmol each of specific oligonucleotides (forward and
reverse primers), and 1 U of Dnazyme II DNA Polymerase (Finnzymes Oy).
PCR amplification was carried out with 30 cycles for TNF- and 40 cycles for glyceraldehyde-3-phosphate dehydrogenase (G3PDH)
(denaturation at 94°C for 1 min, annealing at 60°C for 90 s,
and extension at 72°C for 2 min). PCR products were electrophoresed
on 2% agarose gels containing ethidium bromide and analyzed by an
image densitometer coupled to a computer program (TDI, Gelstation).
Under these conditions, the intensity of amplified bands was
proportional to the amount of cDNA templates (data not shown). The
primer sequences and expected amplified-fragment sizes are shown in
Table 1. G3PDH expression was used as a
control for RNA content and integrity.
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Quantitation of TNF- in sera and culture supernatants.
TNF- protein levels in sera and cell culture supernatants were
measured with an enzyme-linked immunosorbent assay (ELISA) obtained
from Endogen by following the manufacturer's recommendations. Recombinant porcine TNF- was used as the standard, and the assay sensitivity was 38 pg/ml.
Immunohistochemical analyses.
Tissues were snap frozen in
isopentane-liquid nitrogen and stored at 
70°C. Frozen sections of 6 µm were fixed in cold acetone for 10 min and then washed with
phosphate-buffered saline (PBS). Sections were stained with MAbs
recognizing different macrophage subsets or with an anti-CD62E MAb by
an indirect immunoperoxidase technique as previously described
(24). Briefly, frozen sections were incubated for 90 min at
room temperature with hybridoma supernatants. After washing in PBS,
sections were incubated with a 1/40 dilution of polyclonal rabbit
anti-mouse antibodies conjugated with peroxidase (Dako) for 60 min.
After extensive washing with PBS, sections were incubated for 5 min in
a solution of 0.6-mg/ml diaminobenzidine (DAB; Sigma) and 0.02%
hydrogen peroxide in PBS. Finally, they were washed with water,
counterstained with methylene blue, dehydrated, and mounted with DePex
(Serva, Heidelberg, Germany). The MAbs used in this study were MAb
1.2B6 (anti-CD62E), which was obtained from Serotec, and MAb 2A10
(anti-porcine macrophages), which was generated in our laboratory and
whose specificity has been previously reported (8).
-producing cells was performed by incubating tissue
sections with biotin-labeled rabbit anti-TNF- immunoglobulins diluted 1:100 in TBS (Tris-buffered saline, pH 7.6) for 90 min. After
washing with TBS, sections were further incubated with
streptavidin-alkaline phosphatase (Dako) diluted 1/50 in TBS for 60 min. After extensive washing with TBS, a solution containing 1-mg/ml
Fast Red TR, 0.4-mg/ml Naphthol AS-MX, and 0.15-mg/ml levamisole in
Tris buffer (0.1 M pH 7.6) was applied to the sections, and they were
incubated for 25 min. Finally, the sections were washed with water,
counterstained with hematoxylin, and mounted with Clearmount (Zymed).
All steps were carried out in a dark, humidified chamber at room temperature.
In vitro effects of supernatants containing TNF-.
PBMC
were plated in a 96-well plate (Costar, Cambridge, Mass.) at 15 × 104 cells per well in 150 µl of RPMI medium supplemented
with 1% fetal calf serum. Alveolar macrophage cultures were infected
with ASFV isolate E-75 at an MOI of 5. At 8 and 24 h
postinfection, 50-µl volumes of infected culture supernatants were
collected and added to the PBMC. Supernatants from noninfected
macrophages and from macrophages stimulated for 24 h with
1-µg/ml LPS (Sigma) were also added to the PBMC. Recombinant porcine
TNF- (Endogen) (as a potent inducer of apoptosis in lymphocytes) was
used at a final concentration of 6 ng/ml, which had been previously
determined in titration assays (data not shown) to be the highest
nonsaturating concentration to induce significant apoptosis. In order
to block TNF- activity contained in supernatants, they were
preincubated for 2 h with either medium or various amounts of
anti-TNF- MAb (Endogen) (concentrations of 0 to 100 µg/ml, as
indicated). After 6, 12, and 24 h of treatment, PBMC were
collected to analyze DNA fragmentation.
DNA fragmentation assays. An ELISA kit (Boehringer GmbH, Mannheim, Germany) was used to quantitate low-molecular-weight DNA linked to histones by following the manufacturer's instructions. Briefly, a 96-well plate (Costar) was coated with antihistone antibody and incubated overnight at 4°C. Approximately 4 × 104 cells were treated with lysis buffer, and the cytoplasmic extract was obtained by centrifugation. A dilution of the cytoplasmic extract was added to the wells and incubated for 90 min (together with the controls and blanks to measure the background of the assay). After washing, an anti-DNA antibody conjugated with peroxidase was added, and the mixture was incubated for 90 min at room temperature. Finally, 2,2'-azinobis(3-ethylbenzthiazolinesulfonic acid) (ABTS) substrate was added, and color was evaluated by spectrophotometric analysis at 405 nm.
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RESULTS |
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Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
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In vitro induction of TNF- mRNA and protein expression by
ASFV.
To investigate whether ASFV was able to induce the
production of TNF-, comparative PCR analyses were performed on RNA
isolated from alveolar macrophages that had been cultured in the
presence of ASFV (MOI of 5) or UV-inactivated ASFV or in medium alone
(Fig. 1). Total RNA was extracted at 2, 4, 6, 8, and 24 h postinfection (hpi), reversed transcribed into
cDNA, and subsequently amplified with TNF--specific primers.
Equivalent PCR products for G3PDH indicated similar levels of reverse
transcription efficiency and similar amounts of input cDNA between
samples.
|
, 
), p30 (
), or p54 (×) to
those of G3PDH bands; the latter was used as a control (ctrl) for RNA
content and integrity.
mRNA rapidly
increased at 4 hpi (time at which p30 mRNA became detectable), peaked
at 8 hpi, and persisted at least until 24 hpi. In contrast, in cells
cultured with medium alone, TNF- expression was only detectable
during the first 4 h. In cells incubated with UV-inactivated virus, an increase in TNF- expression was also induced but it was
clearly shorter and lower than that obtained in infected cultures.
TNF- protein in culture supernatants harvested at 2, 6, 8, and 24 hpi was determined by ELISA (Fig. 2). As
had been observed by RT-PCR, live virus was more effective for
induction of TNF- than the equivalent dose of a UV-inactivated
preparation. At 8 hpi, the amount of TNF- in supernatants of
infected cultures was sixfold higher than that in mock-infected
cultures, whereas TNF- in supernatants of cells incubated with
UV-inactivated virus was only twofold higher. Production of TNF- in
ASFV-infected cells was also clearly demonstrated by
immunocytochemistry by using a cross-reactive polyclonal rabbit
anti-bovine TNF- serum (data not shown).
|
Levels of TNF- in serum of ASFV-infected animals.
We next
analyzed levels of TNF- in the sera of animals experimentally
infected with virulent strain E-75 of ASFV. Before virus inoculation,
TNF- levels in serum were below the detection level of the ELISA (38 pg/ml). In ASFV-infected pigs, at 4 or 5 days postinfection, serum
TNF- increased to values higher than 100 pg/ml, coincident with the
appearance of leukopenia and other clinical signs and remained elevated
thereafter until the animal died (Fig.
3). No increase in TNF- levels was
observed in the sera of animals inoculated with a saline solution.
|
TNF- expression in tissues from ASFV-infected animals.
The
expression of TNF- mRNA was also analyzed in spleen, liver, lymph
node, alveolar macrophage, and PBMC samples at different days
postinfection (dpi) by using the RT-PCR assay (Fig.
4). In ASFV-infected animals, TNF-
transcripts were clearly detectable in the liver at 2 to 3 dpi and in
the spleen and mesenteric, submandibular, and mediastinal lymph nodes
at 3 dpi, usually corresponding to the time at which mRNA for viral
proteins p30 and p54 began to be detectable in these organs. However,
whereas p30 and p54 expression increased progressively with time or
remained high, TNF- expression rapidly declined. In alveolar
macrophages and PBMC, TNF- mRNA was detectable slightly later, at 4 dpi. TNF--producing cells, showing intense cytoplasmic staining,
were detected by immunohistochemistry in the spleens and lymph nodes of
ASFV-infected animals but not in those of controls inoculated with a
saline solution (Fig. 5). They were
detectable in the spleen at 2 dpi and in lymph nodes at 3 dpi, their
number increasing on the following day (3 dpi in the spleen and 4 dpi
in lymph nodes) and rapidly decreasing thereafter. Most
TNF--producing cells were located in the red pulp of the spleen and
in the sinuses and medulla of the lymph nodes; they exhibited
morphological features of macrophages. The majority of cells in these
areas expressed the 2A10 antigen, a specific marker for porcine
macrophages. These areas also contained most of the ASFV-infected
cells. However, cells expressing viral antigens were more numerous than
TNF--producing cells and could be detected for longer periods.
|
, alveolar macrophages.
|
, was also analyzed. CD62E
expression was detected at 3 to 4 dpi in the small vessels of the
kidney interstitium and the lymph nodes exclusively in ASFV-infected
animals but not in control animals (Fig.
6).
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TNF- production by ASFV-infected macrophages: apoptotic
induction in uninfected lymphocytes.
Since ASFV-infected
macrophages were shown to produce TNF-, we tested the potential
apoptotic effect of supernatants from infected cells on uninfected
swine PBMC. Therefore, PBMC from uninfected pigs were incubated for 0, 6, 12, and 24 h with supernatants of ASFV-infected alveolar
macrophages collected at various times (0, 8, and 24 hpi). Recombinant
porcine TNF- and supernatants from alveolar macrophages stimulated
for 24 h with LPS were used as positive controls; supernatants of
uninfected alveolar macrophages were used as negative controls.
Apoptosis was determined by analysis of DNA fragmentation with an ELISA
to quantify the histone-associated DNA fraction.
. Cell death was observed
after 6 (Fig. 7), 12, or 24 h of incubation with supernatants
(data not shown) collected at 8 (Fig. 7A and C) or 24 (data not shown)
hpi. To confirm the contribution of TNF- to the apoptotic process,
the supernatants were preincubated for 2 h with different amounts of a neutralizing anti-TNF- MAb previous to the addition to PBMC. In
these circumstances, the fraction of dead cells was reduced more than
50%; however, when recombinant porcine TNF- was preincubated with
the neutralizing antibody, cell death was completely abrogated. These
results reflect the involvement of TNF- in lymphocyte apoptosis induced by ASFV-infected macrophage supernatants. However, the incomplete inhibition of cell death observed after anti-TNF- MAb
treatment of these supernatants suggests the presence of additional apoptotic factors.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
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The findings reported here indicate that ASFV infection is
associated with the production of TNF- and suggest a possible contribution of this cytokine to the major clinical manifestations of
the disease. First, in vitro ASFV infection of porcine alveolar macrophages resulted in increased expression of TNF- at both the
mRNA and protein levels. Second, high levels of TNF- protein were
detected in the sera of ASFV-infected animals. Third, TNF--producing cells were detected in tissues of ASFV-infected animals but not in
those from controls.
Tissue macrophages appear to be the main source of TNF-. Abundant
TNF--producing cells with the typical morphology of macrophages were
detected by immunohistochemistry in the spleens and lymph nodes of
ASFV-infected animals. In the different organs analyzed, the increase
in TNF--specific mRNA correlated with the expression of viral genes
encoding p30 or p54. However, TNF- mRNA decreased to basal levels
after 2 days, whereas viral mRNA persisted or increased until death.
Similarly, the number of TNF--producing cells was always lower than
that of ASFV-infected cells. This may reflect the tightly regulated
expression of this cytokine or be a result of the cellular shutoff
produced by virus infection. This down-regulation may be also due to
products released by neighboring cells (IL-10, transforming growth
factor 
, prostaglandins, etc.) or viral products (i.e., I
B
homologue) capable of interfering with TNF- production. On the other
hand, the persistence of high TNF- levels in serum may be explained
by successive waves of viral replication as the virus spreads to
different compartments, reflected by the asynchronous TNF- gene
expression in the different organs. In this context, a substantial
contribution to the TNF- levels in serum could be provided by
circulating monocytes and neutrophils (13), which have been
reported to become infected at a low percentage (30) during
the later periods of infection.
Our results are in contrast to those of Powell et al. (29),
who found that ASFV inhibited the transcription of TNF- and other
proinflammatory cytokines induced by phorbol myristate acetate (PMA).
However, in their experiments, UV-inactivated virus alone was able to
stimulate IFN- and TNF- secretion. The inhibitory effect observed
in infected macrophages was attributed to inactivation by viral protein
A238L of host transcription factor NF-B, which is homologous to
porcine IB. The discrepancy with our results could be due to the
different ASFV isolates tested or the experimental conditions used,
particularly to PMA prestimulation of macrophages. Whereas TNF-
induction by PMA seems to be coupled to NF-B activation (3), ASFV might trigger TNF- production through an
NF-B-independent pathway. In this regard, the NF-B binding sites
on the human TNF- promoter do not appear to be required for LPS or
virus induction of TNF- gene expression in vitro (16).
The mechanisms by which ASFV triggers TNF- production are unknown.
The fact that the UV-inactivated virus is able to induce TNF-
production suggests that the virion or viral proteins, either by
binding to cell surface receptors or after cell entry, might trigger
signals for TNF- synthesis. However, since cells incubated for
8 h with live virus produce fourfold more TNF- than cells incubated with the same amount of UV-inactivated virus, additional mechanisms requiring intracellular viral replication, and/or triggered by viral gene products, seem to be required for enhanced TNF- synthesis.
The IB homologous protein encoded by the virus has been considered
as a strategy to evade the host inflammatory response. However, TNF-
does not show any inhibitory effect on ASFV production in either
monocytes or alveolar macrophages (14). On the other hand, a
viral mutant with the IB homologue deleted is the same as the wild
type in the ability to replicate in macrophage cell cultures and in
infection virulence in domestic pigs (26).
The low rate and lateness of infection of endothelial cells
(17) suggest that the coagulation and vascular disorders
characteristic of ASF do not depend on the direct effect of the virus
on these cells, but more probably they are triggered by factors
released by ASF-infected macrophages. In this regard, TNF- seems a
likely candidate. This cytokine exerts important effects on endothelial cells, leading to loss of the anticoagulant activity of the endothelium and increased permeability and inducing the expression of adhesion molecules for leukocytes and platelets (15, 36). In
addition, TNF- can stimulate the synthesis of other cytokines, such
as IL-1 or IL-6, which have overlapping effects on the endothelium, and
has been implicated as an important mediator of shock and tissue injury
resulting from microbial infection. TNF- also induces a disseminated
form of endothelial cell apoptosis involving ceramide generation, and
this effect was shown to mediate the endotoxic shock syndrome
(19). In ASFV-infected animals, concentrations of TNF- in
serum increased at 3 to 4 dpi and remained elevated until the time of
death. These concentrations of TNF- in serum are similar to those
found in other severe viral hemorrhagic diseases, such as those caused
by dengue virus, Pichinde virus or Junin virus, where TNF- levels
have been correlated with the severity of disease (1, 20,
21).
High expression of E-selectin was detected in the small vessels of the
kidneys and lymph nodes of ASFV-infected animals, which is indicative
of an activated state of the endothelium. TNF- concentrations
equivalent to those found in culture supernatants of ASFV-infected
macrophages were sufficient to induce expression of E-selectin in in
vitro cultures of porcine endothelial cells (4, 34). Other
products released by infected cells (i.e., IL-1, oxygen radicals,
prostaglandins, etc.) might also contribute to activation of the
endothelium, reducing the amount of TNF- required (7,
15). Local differences in TNF- synthesis and/or in the
response of endothelial cells to this cytokine may explain the absence
of E-selectin expression in other organs.
TNF- has been shown to induce apoptosis in different cell
populations (25). Therefore, overproduction of TNF- may
also account for the extensive apoptosis seen in the lymphoid organs in
ASF. For instance, spleen sections of acutely ASFV-infected animals,
presenting high TNF- expression in the red pulp, exhibited extensive
apoptotic destruction of lymphocytes in the periarterial lymphoid
sheath. Recombinant TNF- added to in vitro lymphocyte cultures at
concentrations comparable to those found in culture supernatants of
virus-infected macrophages induced apoptosis. Likewise, supernatants
from ASFV-infected alveolar macrophages were able to induce apoptosis
in lymphocytes. Moreover, preincubation of these supernatants with
neutralizing antibodies to TNF- significantly reduced lymphocyte
apoptosis, suggesting that another factor(s) contributes to lymphocyte
apoptosis, as has been described in other systems (2, 28).
In conclusion, the results of this study demonstrate overproduction of
TNF- following ASFV infection and suggest the contribution of this
cytokine to some of the major clinical manifestations of acute ASF,
such as intravascular coagulation, apoptosis, and shock. In vivo
treatment with anti-TNF- neutralizing antibodies or soluble TNF-
receptors will help to determine the relevance of this cytokine in ASF pathogenesis.
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ACKNOWLEDGMENTS |
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This work was supported by CICYT grant BIO97-0402-CO2-01 and INIA grants SC93-155, SC93-160, and SC97-066. M.G.M. was a recipient of a graduate fellowship from the Spanish Ministry of Education.
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FOOTNOTES |
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* Corresponding author. Mailing address: Centro de Investigación en Sanidad Animal (CISA-INIA), Valdeolmos, 28130 Madrid, Spain. Phone: 34-91-6202300. Fax: 34-91-6202247. E-mail: ezquerr{at}inia.es.
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Abstract
Introduction
Materials and methods
Results
Discussion
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Journal of Virology, March 1999, p. 2173-2180, Vol. 73, No. 3
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Copyright © 1999, American Society for Microbiology. All rights reserved.
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