Previous Article | Next Article 
Journal of Virology, April 2001, p. 3164-3174, Vol. 75, No. 7
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.7.3164-3174.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Identification of T-Cell Epitopes in Nonstructural
Proteins of Foot-and-Mouth Disease Virus
Esther
Blanco,1
Mercedes
Garcia-Briones,1,2
Arantza
Sanz-Parra,1
Paula
Gomes,3
Eliandre
De
Oliveira,3
Mari Luz
Valero,3
David
Andreu,3
Victoria
Ley,1 and
Francisco
Sobrino1,2,*
Centro de Investigación en Sanidad
Animal, INIA, Valdeolmos, 28130 Madrid,1
Centro de Biología Molecular "Severo Ochoa"
(CSIC-UAM), Cantoblanco, 28049 Madrid,2
and Departament de Química Orgànica,
Universitat de Barcelona, 08028 Barcelona,3
Spain
Received 3 July 2000/Accepted 27 December 2000
 |
ABSTRACT |
Porcine T-cell recognition of foot-and-mouth disease virus (FMDV)
nonstructural proteins (NSP) was tested using in vitro
lymphoproliferative responses. Lymphocytes were obtained from outbred
pigs experimentally infected with FMDV. Of the different NSP,
polypeptides 3A, 3B, and 3C gave the highest stimulations in the
in vitro assays. The use of overlapping synthetic peptides allowed the
identification of amino acid regions within these proteins
that were efficiently recognized by the lymphocytes. The sequences of
some of these antigenic peptides were highly conserved among different
FMDV serotypes. They elicited major histocompatibility
complex-restricted responses with lymphocytes from pigs infected
with either a type C virus or reinfected with a
heterologous FMDV. A tandem peptide containing the T-cell peptide
3A[21-35] and the B-cell antigenic site VP1[137-156] also
efficiently stimulated lymphocytes from infected animals in vitro.
Furthermore, this tandem peptide elicited significant
levels of serotype-specific antiviral activity, a result consistent
with the induction of anti-FMDV antibodies. Thus,
inclusion in the peptide formulation of a T-cell epitope derived
from the NSP 3A possessing the capacity to induce T helper activity can allow cooperative induction of anti-FMDV antibodies by B cells.
| |
INTRODUCTION |
The identification and
characterization of T-cell epitopes is important for
understanding protective immunity against pathogens mediated by
CD8+ lymphocytes as well as CD4+
lymphocyte activities (3). Recognition of T-cell
epitopes by lymphocytes from different species and individuals is
restricted by the polymorphism of the major histocompatibility complex
(MHC) molecules, which are responsible for the presentation of foreign antigens by antigen-presenting cells (25). Therefore, the
identification of T-cell epitopes capable of inducing an effective
response, while being widely recognized by MHC alleles frequent in
natural populations of host species, is a problem for the development of new vaccines, particularly those based on synthetic peptides (41).
Foot-and-mouth disease virus (FMDV) is a picornavirus that produces a
highly contagious disease of cloven-hoofed farm animals (36). The FMDV particle contains a positive-strand RNA
molecule of about 8,500 nucleotides, enclosed within an icosahedral
capsid comprising 60 copies each of four virus proteins VP1 to VP4
(reviewed in reference 4). The genome encodes a unique
polyprotein from which the different viral polypeptides are cleaved by
viral proteases (46), including nine different mature
nonstructural proteins (NSP). Each of these NSP, as well as some of the
precursor polypeptides, are involved in functions that are relevant to
the virus life cycle in infected cells (reviewed in reference
37). FMDV shows a high genetic and antigenic variability,
which is reflected in the seven serotypes and the numerous variants
described to date (reviewed in reference 22). FMD control
is mainly implemented by using chemically inactivated whole virus
vaccines (reviewed in reference 5). Viral infection and
immunization with conventional vaccines usually elicit high levels of
circulating neutralizing antibodies, which correlate with protection
against the homologous and antigenically related viruses
(54). However, chemically inactivated vaccines have a
number of disadvantages. Among these are the requirement for a cold
chain to preserve capsid stability, the need for periodic re
vaccination with virus strains antigenically similar to the circulating
viruses, and the risk of virus release during vaccine production
(5). These limitations have led to the search of
alternative, safe immunogens.
The antigenic structure of the virus recognized by B lymphocytes has
been characterized in detail (reviewed in references 10 and
30), from which the main B-cell epitopes are seen to be
located in defined structural motives exposed on the surface of the
capsid (2). A region located in the G-H loop, at positions 140 to 160 of capsid protein VP1, has been identified as the main continuous viral epitope recognized by host B lymphocytes to
produce neutralizing antibodies (6, 9). Peptides spanning
VP1 residues 140 to 160 retain reactivity with neutralizing monoclonal
antibodies (MAbs) and induce neutralizing antibodies when used as
immunogens (6, 9, 10, 30). However, VP1, either purified
from virions or expressed in different systems, has been shown to be a
poor immunogen in terms of production of neutralizing antibodies and protection, probably due to an unproper exposure of site A (9, 22). The B-cell site A has been widely used as an immunogenic peptide (reviewed in reference 9). DiMarchi et al.
(21) reported protection against virus challenge infection
in cattle immunized with a peptide in which the VP1 residues 140 to 160 were colinearly synthesized with those corresponding to VP1 residues
200 to 213. However, further results involving larger number of animals
have shown that these peptides afford limited protection in natural hosts (51). One of the limiting factors of peptide
vaccines may be the absence of T-cell epitopes capable of inducing
the T-cell help required in cooperation with immune B lymphocytes for
the production of specific antibody (15, 41, 48). The induction of anti-FMDV antibodies is T cell dependent
(18). In recent years, several T-cell epitopes
recognized by cattle and swine lymphocytes have been identified in the
FMDV capsid proteins (7, 17, 39, 55). Inclusion of one of
these T-cell epitopes identified in VP1 residues 21 to 40 in a
tandem peptide with the B-cell site A has been shown to overcome
individual nonresponsiveness of cattle to peptide A (17).
However, the recognition of this and other T-cell epitopes
identified in FMDV capsid proteins is significantly restricted by the
MHC polymorphism of the host species (24, 26, 39), and
their potential to improve synthetic vaccines is, therefore, limited.
Yet T-cell epitopes relevant to the induction of a protective
response have also been described in the NSP of several viruses
(13, 27). Consequently, an extension of analysis of T-cell
epitopes to FMDV NSP offers the possibility to broaden the
repertoire of viral epitopes recognized by host immune defenses. In
addition, the low degree of amino acid variation in NSP among different
FMDV serotypes should enable the identification of T-cell epitopes
recognizable in a heterotypic manner, an important requirement for
inclusion in a synthetic vaccine against this virus.
We therefore analyzed the heterotypic lymphoproliferative
responses against different NSP, using lymphocytes from
FMDV-infected pigs. For the NSP 3A, 3B, and 3C, which
consistently induced higher responses, overlapping synthetic peptides
were employed to identify MHC class II-restricted T-cell sites. A
tandem peptide including the B-cell antigenic site VP1[137-156]
colinearly synthesized with one of this T-cell peptides, corresponding
to 3A residues 21 to 35, was capable of eliciting significant levels of
serotype-specific antiviral activity, a finding consistent with the
induction of anti-FMDV antibodies.
| |
MATERIALS AND METHODS |
Experimental infections.
Ten Landrance × Large White
pigs, 3 to 4 months old (obtained from different litters), were
inoculated by intradermal injection of 105 PFU of a type C
FMDV isolate (C-S8) into the coronary matrix of the foot. All of the
animals were free of previous FMD contact, as confirmed by the absence
of detectable anti-FMDV antibodies in the serum. At 120 days
postinfection (p.i.), all pigs were reinfected with 105 PFU
of a type O FMDV isolate (O-BFS). In all cases, infections and
reinfections resulted in fever and lesion (vesicle) development from
day 2 p.i. One animal inoculated with phosphate-buffered saline
(PBS) was used as a negative control.
Fusion proteins.
Different NSP, as well as the VP1 capsid
protein from a type O FMDV isolate (O1Kb), were expressed in
Escherichia coli, as fusion proteins with the N-terminal
part of MS2 polymerase (49). Figure
1A shows the viral polypeptides used in
this study. Proteins were obtained from heat-induced bacterial cultures
by sonication and purification using 7 M urea. Viral polypeptides were
tested in lymphoproliferative assays as described elsewhere
(39). Briefly, 20 µg of each polypeptide was separated
using discontinuous 12% polyacrylamide gel electrophoresis (wt/vol)
gels and transferred onto nitrocellulose sheets. The different viral
polypeptides were identified by Western blotting using protein-specific
rabbit antisera (38). Nitrocellulose fragments containing
individual viral polypeptides, as well as control fragments containing
nonviral proteins, were solubilized in dimethyl sulfoxide as described
earlier (1) and used in the proliferation assays.
View larger version (35K):
[in this window]
[in a new window]
|
FIG. 1.
Heterotypic lymphoproliferative response to viral
polypeptides by FMDV-infected pigs. Fusion polypeptides from type O
isolate (O1Kb) were used to in vitro stimulate PBMC from pigs
infected with type C isolate (C-S8), as described in Materials and
Methods. (A) Schematic representation of FMDV genomic RNA
showing the location in the viral polyprotein of the fusion
polypeptides used in this study. (B) Time course study of the
lymphoproliferative response to FMDV polypeptides by lymphocytes from
infected pigs 1 and 2. Assays were performed with lymphocytes
obtained at 0, 4, 10, 21, 38, 50, 63, 70, 81, and 93 d.p.i. In
those d.p.i. (i.e., from 10 to 80) in which positive SI were observed,
peak responses were obtained with a nitrocellulose-bound protein
concentration of 2.5 µg/ml, with the following exceptions in which
the highest stimulation was obtained at a concentration of 0.5 µg/ml:
VP1, day 10 (pigs 1 and 2); 3ABC, day 50 and 63 (pig 1) and days 63, 70, and 80 (pig 2); 3C, day 63 (pig 2); and 3D, day 63 (pig 1). (C)
Peak lymphoproliferative response to FMDV polypeptides by the four pigs
(animals 1 to 4) analyzed. The dotted line represent the value (SI
 3), above which responses were considered positive. The d.p.i.
values, followed by the nitrocellulose-bound protein
concentration (in micrograms per milliliter) corresponding to each
of the responses, are shown above each bar (i.e., "70/2.5"
indicates an SI obtained at 70 d.p.i. with 2.5 µg of nitrocellulose-bound protein per ml). In all cases, The results
are expressed as SI as described in Materials and
Methods. The standard deviations of these values never
exceeded 15% of the mean. A control animal was inoculated with PBS.
The background cpm values (obtained with lymphocytes incubated with
medium alone) were 502 (pig 1), 293 (pig 2), 1,140 (pig 3), 971 (pig
4), and 508 (control pig 5).
|
|
Peptide synthesis.
A total of 83 pentadecapeptides covering
the entire 3ABC precursor sequence of FMDV isolate C-S8 (29,
53) and overlapping each other by 10 residues were prepared.
Their sequences and locations on the corresponding NSP are shown in
Table 1. The peptides were synthesized in
N-terminal free, C-terminal carboxamide form by 9-fluorenylmethoxy
carbonyl-based solid-phase methods (32) in an Abimed 422 multiple synthesizer, as previously described (31). After
trifluoroacetic acid cleavage, the crude materials were analyzed for
identity by MALDI-TOF (matrix-assisted laser desorption ionization-time of flight) mass spectroscopy and for purity by reversed-phase high-pressure liquid chromatography (HPLC). They were
found to be correct by both criteria. Any sequences that failed to give
the expected mass and/or that showed <75% purity by HPLC were
resynthesized under carefully controlled conditions (manual assembly,
ninhydrin monitoring, recoupling as required) until the above
requirements were met.
In addition, two tandem peptides containing the sequence of the
continuous B-cell epitope VP1[137-156] juxtaposed to the T-cell
epitope 3A[21-35], in the two possible orientations (peptides
BT
and TB; Table
1), were prepared. Both peptides were synthesized
as
C-terminal carboxamides by Boc-based solid-phase methods
(
12)
in semiautomated mode, with systematic ninhydrin
control and recoupling
as required. Preliminary deprotection-cleavage
experiments (HF-
p-cresol,
9:1, 0°C, 1 h) showed
substantial oxidation to sulfoxide of the
Met residue in each sequence.
In order to minimize this side reaction,
acidolysis of the peptide
resins was conducted under low-high
hydrogen fluoride conditions
(
52). Even so, crude complexes
were obtained in both
cases, requiring two consecutive reversed-phase
HPLC purification steps
to give fairly homogeneous (>90%) products,
with correct amino acid
analysis and MALDI-TOF mass spectral data.
B-cell antigenicity of these
tandem peptides was confirmed as
they reacted in dot blot assays
against MAbs that recognized the
peptide VP1[137-156]
(
7).
Lymphoproliferation assays.
Proliferation assays with
porcine lymphocytes were performed as described elsewhere
(39). Blood was collected in 5 µM EDTA and used
immediately for the isolation of peripheral blood mononuclear cells
(PBMC) (45). Assays were performed in 96-well round-bottom microtiter plates (Nunc). Briefly, 2.5 × 105 PBMC per
well were cultured in triplicate, in a final volume of 200 µl, in
complete RPMI, 10% (vol/vol) fetal bovine serum, and 50 µM
2-mercaptoethanol in the presence of various concentrations (fivefold
dilutions) of the following: FMDV, ranging from 4 × 103 to 2.5 × 106 PFU/ml; nitrocellulose-bound
viral polypeptides, ranging from 0.02 to 2.5 µg/ml; and synthetic
peptides, ranging from 0.8 to 100 µg/ml. Control cultures without
viral antigens were included. Cells were incubated at 37°C in 5%
CO2 for 4 days. After incubation, each well was pulsed with
0.5 µCi of [methyl-3H]thymidine for 18 h. The cells were collected using a cell harvester, and the
incorporation of radioactivity into the DNA was measured by liquid
scintillation in a Microbeta counter (Pharmacia). Results were
expressed as stimulation indexes (SI) (mean counts per minute [cpm]
of stimulated cultures/mean cpm of control cultures).
Lymphoproliferations that induced SI of 3 were considered as positive.
For the analysis of the role played by the MHC in the
lymphoproliferations, the following murine anti-swine MHC swine
leukocyte
antigen (SLA) MAbs were used: 74-11-10 (immunoglobulin G
[IgG2b])
anti-SLA class I (
35) and MSA-3 (IgG2a)
anti-SLA class II (
28).
The procedure was as described
previously (
7). A total of 15
µl of the appropriate MAb
(1 mg/ml) was added per well of PBMC,
stimulated with peptides as
described above, at the beginning
of culture, and an additional 15 µl
per well was added after 24
h. Finally, the plates were processed
as described above. These
concentrations had been identified to give
maximum specific blocking
of SLA-restricted responses and have been
successfully employed
to such ends (
7). The anti-MHC class
II MAb concentrations
have been shown to inhibit concanavalin A-, but
not phorbol esters
plus PMA ionophore (PMA)-, induced proliferation of
swine PBMC,
while the anti-MHC class I MAb did not affect these
proliferations
(
11). Under the experimental conditions
used, FMDV peptide-induced
lymphoproliferations were not significantly
inhibited by MAbs
against the SWC3 monocytic marker and the
TCR
which acted as
relevant negative controls (
7).
Detection of FMDV neutralizing activity in supernatants of immune
PBMC stimulated with peptides.
About 106 PBMC from
reinfected pigs were in vitro stimulated, as described above, with 20 µg of the different peptides per ml. PBMC from infected animals
incubated in the presence of medium alone were used as controls.
Culture supernatants were collected after 4, 7, and 13 days of
stimulation, and the FMDV neutralizing activity was analyzed using a
modification of the PFU reduction assay previously described
(40). Briefly, ca. 60 to 80 FMDV PFU were incubated for 45 min, with or without 125 µl of the supernatants. The mixtures were
employed to infect BHK-21 cell monolayers (ca. 106 cells),
and the infection was allowed to proceed for 18 h in the presence
of low-melting-point agarose (1.3%). The monolayers were fixed and
stained with 10% (vol/vol) acetic acid-0.5% (wt/vol) crystal violet,
and virus PFU were scored. PFU reductions were expressed as the
percentage of PFU observed in the presence of peptide-stimulated
supernatants with respect to the PFU in the presence of supernatant
from PBMC incubated with medium alone.
| |
RESULTS |
Lymphoproliferative responses to FMDV NSP.
In order to study
the contribution of the NSP to the T-cell response elicited by FMDV in
swine, type O polypeptides expressed in E. coli (Fig. 1A)
were used to stimulate in vitro PBMC from four outbred pigs (animals 1 to 4) infected with type C isolate (C-S8). The experimental approach
was designed to identify regions conserved among different FMDV
serotypes, which were capable of inducing heterotypic T-cell responses
in lymphocytes from domestic pigs. Lymphoproliferative responses
against the different polypeptides were monitored using PBMC obtained
from 0 to 100 days p.i. (d.p.i.). The magnitude of the responses
observed showed animal-to-animal variation, but a consistent trend was
noted. Positive lymphoproliferations (SI 3) against NSP and VP1
capsid protein (also included in this analysis) were detected from day
38 p.i. until day 70 p.i., and the higher SI were observed at
between 38 and 50 d.p.i. No stimulations were observed with PBMC
obtained from the animals prior to infection (day 0 p.i.) nor from
a control animal inoculated with PBS (pig 5). Figure 1B shows the
results found with cells from the highest-responder pigs 1 and 2, which
were representative of the results obtained with cells from the four
animals analyzed. In general, the responses were dose dependent, and
the higher SI were obtained with nitrocellulose-bound protein at from
0.5 to 2.5 µg/ml. Figure 1C shows the peak responses found in each of
the animals analyzed. Polypeptides 3AB and 3C were recognized by
the lymphocytes from all the animals analyzed. Proteins 2C, 3D, and VP1
were recognized by cells from only two of the four pigs. These
results suggest the presence within the 3ABC polypeptide region of
T-cell epitopes conserved among FMDV serotypes, which are
consistently recognized by lymphocytes from domestic pigs.
Identification of T-cell epitopes in 3A, 3B, and 3C.
In
order to characterize further the T-cell epitopes located in the
3ABC region, a set of overlapping peptides (15-mer), covering proteins
3A, 3B, and 3C of the C-S8 virus, was synthesized. These peptides were
employed to stimulate in vitro lymphocytes from infected pigs (see
Materials and Methods and Table 1 for details). For this purpose, six
additional pigs (animals 6 to 11) were experimentally infected with
C-S8 virus, and their PBMC were isolated on days 14 and 28 p.i.
None of the peptides induced positive SI in PBMC obtained from
these animals before infection (data not shown). In general, the
responses against individual peptides were already detectable at
day 14 p.i., being more consistent at day 28 p.i. They
were dose dependent, and the highest values were obtained with peptide
concentrations ranging from 4 to 100 µg/ml (Table 2). Among the 83 overlapping peptides
tested, 45 did not induce significant proliferations in any of the pigs
analyzed. The peak responses against the 19 peptides that induced
positive SI in at least four of the six animals are indicated in Table
2. The magnitude of the response against individual peptides correlated with the SI observed against the whole virus, but the pattern of
peptide recognition was different in each of the animals studied. However, three individual peptides consistently stimulated PBMC from
the six pigs analyzed: 3A-5[21-35], 3C-12[56-70], and
3C-27[131-145] (see Table 2).
View this table:
[in this window]
[in a new window]
|
TABLE 2.
Peptides corresponding to 3A, 3B, and 3C that were
significantly recognized by lymphocytes from FMDV-infected pigs
|
|
For studies on the T-cell antigenic specificity elicited upon
challenge, animals 7 to 11 were reinoculated 4 months after
the initial
infection with a heterologous type O FMDV virus (O-BFS).
The five pigs
developed an acute episode of the disease, and PBMC
obtained at days
10, 21, and 35 postreinfection (p.r.i.) were
used to perform
lymphoproliferative assays in which the 3ABC peptides
were used as
stimulator antigens. In general, the responses against
peptides were
detected at day 21 p.r.i., being more consistent
at day 35 p.r.i. The responses were dose dependent, and the highest
values were
obtained with peptide concentrations (4 to 100 µg/ml)
similar to
those found with cells after the first infection (Table
3). In this experiment, positive SI were
also induced with peptide
concentrations lower than those effective
with cells from the
initially infected animals (0.8 µg/ml; data not
shown). The efficacy
of the heterologous restimulation showed
individual variation
among the animals. A clear boost of individual
peptide responses
was observed for lymphocytes from animal 8. Lymphocytes from animals
9, 10, and 11 showed an increased, albeit of
lower magnitude,
in most of the SI, and the responses of PBMC from
animal 7 were
lower than those observed after the first infection.
Table
3 summarizes the SI obtained with the peptides that induced
positive
responses in at least three of the five animals analyzed.
View this table:
[in this window]
[in a new window]
|
TABLE 3.
Peptides corresponding to 3A, 3B, and 3C, that were
significantly recognized by lymphocytes from FMDV-reinfected pigs
|
|
Lymphocytes from reinfected pigs responded to 11 of the 19 peptides
identified as antigenic after analyses with cells obtained
following
the first infection (Table
3). Peptides 3A-3, -5, -6,
and -9, peptide
3B-4, and peptides 3C-12, -13, -20, -25, -34,
and -40, previously
identified as good stimulators (see Table
2), also induced positive
responses in at least three of the
five reinfected pigs. In addition,
the following new peptides
induced proliferation in lymphocytes taken
from the majority of
the reinfected animals analyzed: 3A-17; 3B-2; and
3C-26, -30,
and -32. Again, several individual peptides induced
lymphoproliferative
responses by cells from the five animals upon
heterologous reinfection
(Table
3): 3A-5[21-35], 3C-12[56-70],
3C-13[61-75], 3C-34[166-180],
and 3C-40[196-210].
Representative dose responses induced by some
of these peptides in PBMC
from infected and reinfected animals
are shown in Fig.
2.
View larger version (31K):
[in this window]
[in a new window]
|
FIG. 2.
Effect of peptide dose on the proliferative response of
PBMC obtained from pigs 8, 9, and 10 at days 28 p.i. and 35 p.r.i. The values corresponding to 0 on the x axis indicate
the background of the assay (PBMC incubated with medium alone).
|
|
SLA restriction of the anti-peptide response.
Information
about the SLA restriction of the detected lymphoproliferative responses
was obtained using MAbs against SLA class I and class II. These were
used to inhibit in vitro the lymphoproliferations induced in cells from
reinfected pigs. The peptides 3A-3[11-25], 3A-5[21-35],
3C-34[166-180], and 3C-40[196-210] were selected for this study
because they induced consistent responses in cells from most of the
analyzed animals, after both the first infection and the heterologous
re infection (Tables 2 and 3). Results showed the highest inhibition of
peptide-induced lymphoproliferation (>75%) when the anti-SLA class II
MAb was used. This is consistent with lymphoproliferations induced by
peptides being dependent on CD4+ T -helper lymphocyte
activities (Table 4). The anti-SLA class I MAb was also inhibitory, but the magnitude of inhibition was generally lower than that observed with the anti-SLA class II antibody.
Antigenicity of tandem peptides including B- and T-cell
epitopes.
The potential of the T-cell epitopes identified
in NSP to improve vaccine formulation of FMDV synthetic peptides
requires that T-cell epitopes remain immunostimulatory when in
combination with B-cell epitopes. In order to investigate this
point, the immunostimulatory potential of the T-cell peptide
3A-5[21-35] was further analyzed by using tandem peptides in which
this epitope was colinearly synthesized with the B-cell site
VP1[137-156]. Two possible orientations were used: peptides BT and
TB (Table 1). With lymphocytes from pigs 7, 9, 10, and 11, the tandem
epitopes induced lymphoproliferative responses in vitro upon
infection with C-S8 virus, as shown in Fig.
3A. The responses were dose dependent,
and the highest SI was obtained with a peptide concentration of 20 µg/ml. Positive SI were found with cells from all four animals stimulated with peptide T3A-5B, whereas only cells from
animals 7 and 11 responded to peptide BT3A-5. The SI of the
latter cells were lower than those induced by peptide
T3A-5B. In this experiment, peptide 3A-5[21-35] was
also recognized with an SI lower than those found using peptide
T3A-5B.
View larger version (29K):
[in this window]
[in a new window]
|
FIG. 3.
Lymphoproliferative responses to peptides
3A-5[21-35], BT3A-5, and T3A-5B. The data
shown correspond to peak responses of lymphocytes obtained at days
28 p.i. with C-S8 virus (A) and 21 p.r.i. with the
heterologous O-BFS virus (B). The standard deviations are indicated.
The peptide concentrations giving the SI shown were 20 µg/ml, except
for pig 9 (in panel A) in which the peak response was obtained with 100 µg/ml. The background cpm levels were 405 (pig 7), 450 (pig 9), 525 (pig 10), and 345 (pig 11) (A) and 302 (pig 7), 214 (pig 8), and 258 (pig 10) (B).
|
|
Upon reinfection with the heterologous O-BFS virus, lymphocytes from
pigs 7, 8, and 10 responded to T
3A-5B, again with SI
higher
than those induced by peptide 3A-5[21-35] alone (Fig.
3B).
Thus,
tandem peptide T
3A-5B stimulates in vitro lymphocytes from
both infected and reinfected
animals.
It was then interesting to address whether the incorporation of
3A-5[21-35] into the tandem peptide could result in the stimulation
of T cells to provide the necessary immunological help for
antigen-stimulated
B lymphocytes. To this end, the stimulation of T
cells by peptide
T
3A-5B was analyzed in terms of
cooperation with the induction
of an antiviral humoral response.
Lymphocytes from reinfected
pig 8 were stimulated in vitro with
peptides T
3A-5B, T, or B.
At different times
poststimulation, the presence of anti-FMDV
activity in the supernatants
was measured using a plaque reduction
assay. Significant PFU reductions
were detected using supernatants
from cultures stimulated with peptide
T
3A-5B from the fourth day,
reaching a maximum with day 7 supernatants (ca90%) (Fig.
4). The
PFU
reductions were higher than those obtained using supernatants
from
cultures stimulated by peptides T and B separately. In addition,
the
antiviral activity was restricted to the homologous virus
C-S8, since
no plaque reduction was detected when a type O FMDV
was used in the
assay (Fig.
4). Thus, a serotype-specific anti-FMDV
activity,
consistent with the induction of anti-FMDV neutralizing
antibodies, was
detected upon stimulation of immune lymphocytes
with peptide
T
3A-5B.
View larger version (20K):
[in this window]
[in a new window]
|
FIG. 4.
FMDV PFU reduction by supernatants of immune PBMC
stimulated in vitro with viral peptides. The data correspond to PBMC
from pig 8 (obtained at day 35 p.r.i.) assayed at different days
of in vitro stimulation with 20 µg of the indicated peptides per ml.
The results are expressed as the percent inhibition in the PFU
recovered from cells stimulated with each peptide with respect to the
PFU observed with a control supernatant incubated with medium alone.
The assay was performed using two FMDV isolates of different serotypes:
C-S8 (type C) and O-BFS (type O). The standard deviations are
indicated.
|
|
| |
DISCUSSION |
In the present studies the antigenic specificity of the porcine
(an important natural host of this virus) T-cell response against FMDV
NSP was analyzed. The aim was the identification of T-cell epitopes
in NSP widely recognized by domestic pigs, the sequences of which were
conserved among different FMDV serotypes. Animals were selected from
different litters to ensure a representative sample of outbred pigs and
to bring porcine MHC polymorphism in the T-cell epitope
recognition into the study. FMDV NSP are absent, or incorporated in
very small amounts, in the virus particle (34). Therefore,
the analyses used animals experimentally infected with a type C FMDV isolate.
T-cell antigenicity of the NSP was first analyzed in terms of the
capacity of different polypeptides to stimulate in vitro T cells from
the infected animals. A heterotypic lymphoproliferative response
against NSP in cells from FMDV-infected pigs was tested. Lymphoproliferations were detected from day 38 to day 70 p.i. Although the SI showed animal-to-animal variations, polypeptides 3AB
and 3C induced specific and consistent responses in lymphocytes from
all animals analyzed. Polypeptides 2B and 3D and capsid protein VP1
were not recognized by all the animals (Fig. 1C). This finding contrasts with the recognition of type O FMDV 3D as an
immunodominant T-cell determinant by cattle lymphocytes, as
recently reported (16). In addition to differences between
cattle and swine in terms of antigenic recognition patterns, the
lower antigenicity of 3D for porcine lymphocytes may also reflect
differences between FMDV type C and type O. The low heterotypic
recognition of VP1 is consistent with the sequence divergence that
exists between type O and type C FMDV.
Overlapping synthetic peptides allowed a detailed analysis of the
T-cell epitopes recognized in proteins 3A, 3B, and 3C. Despite animal to animal variation, 19 peptides were stimulated in vitro lymphocytes from, at least, four of the six infected pigs analyzed (Table 2). The responsive peptides define T-cell regions efficiently recognized by swine lymphocytes at the following amino acid positions: 3A[11-55] and -[121-135], 3B[13-23] and -[39-53], and
3C[51-75],-[91- 110], -[121-150], -[161-180], and
-[191-210]. Eleven of these peptides were also recognized by
lymphocytes from at least three of the five heterotypically reinfected
pigs analyzed (Table 3). Five new peptides, which did not induced in
vitro responses in the initially infected animals, became responsive
upon the induction of a secondary response (Table 3). The efficacy of
the heterologous restimulation was uneven among the five animals
studied. A clear boost of individual peptide responses was only
observed for lymphocytes from animal 8. Although the number of animals
used for this type of study was not sufficient for statistical
demonstration, we think that the data are consistent with the
identification of a number of peptide epitopes in the nonstructural
polypeptides 3A, 3B, and 3C of FMDV, which are capable of stimulating
porcine T cells following infection with viruses of different
serotypes, and that some of them may boost primed lymphocytes.
SLA class II MAb efficiently inhibited the lymphoproliferative
response. This demonstrated the involvement of CD4+ Th
lymphocytes in the recognition of some of the stimulatory peptides
(Table 4). Anti-class I MAb gave lower inhibitions, in agreement with
the previous reports on porcine lymphoproliferation against whole virus
(14, 45) and FMDV capsid protein peptides (7). These
inhibitions might relate to the high proportion of CD8+
CD4+ double-positive cells found in swine
(58), dominated by memory Th lymphocytes (50,
59). Certainly, it must also be considered that the animals were
infected with FMDV and, therefore, that stimulation of CD8+
cells through class I presentation could have occurred
(14). The implication of CD8+ lymphocytes in
protective responses to FMDV remains largely unknown and thus its
characterization was not pursued here. Attempts to obtain porcine
T-cell clones, a highly valuable tool for understanding the antigenic
specificity and function of T cells, have had very limited success.
Thus, as a first step in the characterization of the immune responses
induced by the T-cell epitopes thus for identified, our attention
was focused on the potential of these peptides to stimulate
CD4+ cells to provide T help to immune B lymphocytes. In
this way, we attempted to identify T-cell epitopes that could
enhance the induction of anti-FMDV antibodies by peptide vacines. For
practical reasons, such T-cell epitopes should be conserved among
different FMDV serotypes. Peptides 3A-3[11-25], 3A-5[21-35],
3C-25[121-135], and 3C-34[166-180] do indeed show amino acid
sequences completely conserved among serotypes A, O, and C (Table
5). These 3A and 3C peptides are
frequently and efficiently recognized by porcine lymphocytes in both a
homotypic and heterotypic manner. Consequently, they constitute
potential candidates for inclusion in a peptide vaccine formulation.
The colinear expression of T-helper and B-cell epitopes in peptide
vaccines can result in the enhancement of antibody responses (8,
17). The design of functional combinations of T-cell and B-cell
epitopes is rather empirical (19, 47) and should maintain the immunostimulatory ability of the B- and T-cell components. T-cell peptide 3A-5[21-35] consistently stimulated lymphocytes from
all initially infected and reinfected animals analyzed in this study,
as well as lymphocytes from four additional FMDV-infected domestic pigs
(unpublished results). Therefore, peptide 3A-5[21-35] was employed
to explore the potential of tandem peptides including the
immunodominant B-cell site VP1[137-156], with either the BT or the
TB orientation, to stimulate lymphocytes from infected animals. We
first analyzed whether these tandem peptides retained the capacity to
induce lymphoproliferation of immune lymphocytes. Each of the tandem
peptides was recognized by immune lymphocytes, with T3A-5B
being the most efficient stimulator of lymphocytes from both initially
infected and reinfected animals (Table 3). Different factors may
mediate the higher stimulations observed with tandem peptide
T3A-5B: among these factors is the influence of the
different flanking sequences on the binding to MHC molecules that could
modify lymphocyte activation (56) or on the susceptibility of the T-cell epitopes to proteases in antigen processing
(20).
The induction of FMDV neutralizing antibodies by immune PBMC in
response to in vitro viral stimulation has been previously reported as
an indicator of T-cell-B-cell cooperation (40). Interestingly, a significant FMDV PFU reduction activity (up to 90%)
was detected in supernatants of PBMC upon incubation with peptide
T3A-5B under conditions in which the inhibitions induced by
supernatants of PBMC stimulated with peptide A[21-35] or
3A-5[21-35] did not exceed 20%. This reduction was serotype
specific, since it was not observed with a type O virus (Fig. 4). These
results are consistent with the induction of anti-FMDV antibodies in
the peptide-stimulated cultures, and new experiments are being
conducted to further characterize the antiviral activity induced.
Inclusion of FMDV T-cell epitopes may enhance the immunogenicity of
subunit and peptide vaccines. According to the model of intermolecular-intrastructural help (33, 43), B cells can be activated by T cells resulting from the stimulation by epitopes derived from a different protein, provided that both proteins are
associated in a common complex. Whether 3ABC and viral structural proteins, VP1 in particular, may become associated in FMDV-infected cells remains to be studied. On the other hand, the stimulation of T
cells by viral peptides may participate not only in providing T-cell
help to B lymphocytes but also in eliciting a synergistic response
against the virus infection. T cells secrete cytokines such as gamma
interferon and interleukins that might play an important role in the
protection against the virus (23, 57). Consistent with
this hypothesis are the results described recently (46) that show that immunization with a recombinant adenovirus expressing the P1 polypeptide elicits partial protection against FMDV in pigs and
cattle in the absence of antiviral antibody response. To explore these
possibilities, experiments are in progress to assess the immunogenicity
in pigs of combinations of the B-cell site VP1[140-160] and the
T-cell peptides identified here.
| |
ACKNOWLEDGMENTS |
We thank C. Sanchez for excellent work in the animals
experiments; J. I. Núñez and M. A. Jimenez for
experimental help and support; and J. Domínguez, A. Ezquerra,
F. Alonso, A. Canals, and K. McCullough for advice and constructive
discussions. We also thank E. Beck for providing plasmids expressing
FMDV NSP.
Work at CISA-INIA and CBMSO was supported by CICYT (grant
BIO99-0833-02-01), by the EU grants FAIR CT97-3665 and CT96-1317, and
by the Fundación Ramón Areces. Work in Barcelona was
supported by DGES (grant PB97-0873), by the EU (grant FAIR CT97-3577),
and by Generalitat de Catalunya (CERBA). P.G. thanks the
Fundaç
o Calouste Gulbenkian (Lisbon, Portugal) for her
Ph.D. grant and the University of Porto (Porto, Portugal) for a
temporary leave from teaching duties.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: CBMSO,
Cantoblanco 28049, Madrid, Spain. Phone: 34-91-6202300. Fax:
34-91-6202247. E-mail: fsobrino{at}cnb.uam.es.
| |
REFERENCES |
| 1.
|
Abou-Zeid, C.,
E. Filley,
J. Steele, and G. A. W. Rook.
1987.
A simple method for using antigens separated by polyacrylamide gel electrophoresis to stimulate lymphocytes in vitro after converting bands cut from Western blots into antigen-bearing particles.
J. Immunol. Methods
98:5-10[CrossRef][Medline].
|
| 2.
|
Acharya, R.,
E. Fry,
D. Stuart,
D. Rowlands, and F. Brown.
1989.
Three-dimensional structure of foot-and-mouth disease virus at 2.9 × resolution.
Nature
337:709-716[CrossRef][Medline].
|
| 3.
|
Ahmed, R., and C. A. Biron.
1999.
Immunity to viruses, p. 1295-1334.
In
W. E. Paul (ed.), Fundamental immunology. Lippincott-Raven Publishers, New York, N.Y.
|
| 4.
|
Bachrach, H. L.
1977.
Foot-and-mouth disease virus, properties, molecular biology and immunogenicity, p. 3-32.
In
J. A. Romberger (ed.), Virology in agriculture. Beltsville Symposia in Agricultural Research. I. Allanheld, Montclair, N.J.
|
| 5.
|
Barteling, S. J., and J. Vreeswijk.
1991.
Development in foot-and-mouth disease vaccines.
Vaccine
9:75-88[CrossRef][Medline].
|
| 6.
|
Bittle, J. L.,
R. A. Houghten,
H. Alexander,
T. M. Shinnick,
J. G. Sutcliffe, and R. A. Lerner.
1982.
Protection against foot-and-mouth disease by immunization with a chemically synthesized peptide predicted from the viral nucleotide sequence.
Nature
298:30-33[CrossRef][Medline].
|
| 7.
|
Blanco, E.,
K. McCullough,
A. Summerfield,
J. Fiorini,
D. Andreu,
C. Chiva,
E. Borrás,
P. Barnett, and F. Sobrino.
2000.
Interspecies MHC-restricted Th cell epitope on foot-and-mouth disease virus capsid protein VP4.
J. Virol.
74:4902-4907[Abstract/Free Full Text].
|
| 8.
|
Borrás-Cuesta, F.,
A. Petit-Camurdan, and Y. Fedon.
1987.
Engineering of immunogenic peptide by co-linear synthesis of determinants recognized by B and T cells.
Eur. J. Immunol.
17:1213-1215[Medline].
|
| 9.
|
Brown, F.
1992.
New approaches to vaccination against foot-and-mouth disease.
Vaccine
10:1022-1026[CrossRef][Medline].
|
| 10.
|
Brown, F.
1995.
Antibody recognition and neutralization of foot-and-mouth disease virus.
Semin. Virol.
6:243-248.
|
| 11.
|
Bullido, R.,
N. Domenech,
B. Alvarez,
F. Alonso,
M. Babín,
A. Ezquerra,
E. Ortuño, and J. Domínguez.
1997.
Characterization of five monoclonal antibodies specific for swine class II major histocompatibility antigens and cross-reactivity studies with leukocytes of domestic animals.
Dev. Comp. Immunol.
21:311-322[CrossRef][Medline].
|
| 12.
|
Carreño, C.,
X. Roig,
J. J. Cairó,
J. A. Camarero,
M. G. Mateu,
E. Domingo,
E. Giralt, and D. Andreu.
1992.
Studies on antigenic variability of C strains of foot-and-mouth disease virus by means of synthetic peptides and monoclonal antibodies.
Int. J. Peptide Protein Res.
39:41-47[Medline].
|
| 13.
|
Celis, E.,
J. Larson, Jr.,
L. Otvos, and W. H. Wunner.
1990.
Identification of a rabies virus T cell epitope on the basis of its similarity with a hepatitis B surface antigen peptide presented to T cells by the same MHC molecule (HLA-DPw4).
J. Immunol.
145:305-310[Abstract].
|
| 14.
|
Childerstone, A. J.,
J. Cedillo-Baron,
R. Foster-Cuevas, and M. E. Parkhouse.
1999.
Demonstration of bovine CD8+ T-cell responses to foot-and-mouth disease virus.
J. Gen. Virol.
80:663-669[Abstract].
|
| 15.
|
Collen, T.
1994.
Foot-and-mouth disease (aphthovirus): viral T cell epitopes, p. 173-197.
In
B. M. L. Goddeevis, and I. Morrison (ed.), Cell mediated immunity in ruminants. CRC Press, Inc., Boca Raton, Fla.
|
| 16.
|
Collen, T.,
J. Baron,
A. Childerstone,
A. Corteyn,
T. R. Doel,
M. Flint,
M. García-Valcarcel,
M. E. Parkhouse, and M. D. Ryan.
1998.
Heterotypic recognition of recombinant FMDV proteins by bovine T-cells: the polymerase (P3Dpol) as an immunodominant T-cell immunogen.
Virus Res.
56:125-133[CrossRef][Medline].
|
| 17.
|
Collen, T.,
R. DiMarchi, and T. R. Doel.
1991.
A T cell epitope in VP1 of foot-and-mouth disease virus is immunodominant for vaccinated cattle.
J. Immunol.
146:749-755[Abstract].
|
| 18.
|
Collen, T.,
L. Pullen, and T. R. Doel.
1989.
T cell-dependent induction of antibody against foot-and-mouth disease virus in a mouse model.
J. Gen. Virol.
70:395-403[Abstract/Free Full Text].
|
| 19.
|
Cox, J. H.,
J. Ivanyi,
D. B. Young,
J. R. Lamb,
A. D. Syred, and M. J. Francis.
1988.
Orientation of epitopes influences the immunogenicity of synthetic peptide dimers.
Eur. J. Immunol.
18:2015-2019[Medline].
|
| 20.
|
Del Val, M.,
H. J. Schlicht,
T. Ruppert,
M. J. Reddehase, and U. H. Koszinowski.
1991.
Efficient processing of an antigenic sequence for presentation by MHC class I molecules depends on its neighbouring residues in the protein.
Cell
66:1145-1153[CrossRef][Medline].
|
| 21.
|
DiMarchi, R.,
G. Brooke,
C. Gale,
V. Cracknell,
T. Doel, and N. Mowat.
1986.
Protection of cattle against foot-and-mouth disease by a synthetic peptide.
Science
232:639-641[Abstract/Free Full Text].
|
| 22.
|
Domingo, E.,
M. G. Mateu,
M. A. Martínez,
J. Dopazo,
A. Moya, and F. Sobrino.
1990.
Genetic variability and antigenic diversity of foot-and-mouth disease virus, p. 233-266.
In
E. Kurstak, R. G. Marusyk, S. A. Murphy, and M. H. V. Van-Regenmortel (ed.), Applied virology research, vol. 2. Virus variation and epidemiology. Plenum Publishing Corp., New York, N.Y.
|
| 23.
|
Emile, D.,
M. Peuchmaur,
M. C. Maillot,
M. C. Crevon,
N. Brouse,
J. F. Delfraissy,
J. Dromont, and P. Galanaud.
1990.
Production of interleukins in human immunodeficiency virus 1 in replicating lymph nodes.
J. Clin. Investig.
86:148-159.
|
| 24.
|
García-Briones, M. M.,
G. Russell,
E. Carrillo,
E. L. Palma,
O. Taboga,
C. Tami,
F. Sobrino, and E. J. Glass.
2000.
Association of bovine DRB3 alleles with the immune response to foot-and-mouth disease virus peptides and protection against viral challenge.
Vaccine
19:1167-1171[CrossRef][Medline].
|
| 25.
|
Germain, R. N.
1999.
Antigen processing and presentation, p. 287-340.
In
W. E. Paul (ed.), Fundamental immunology. Lippincott-Raven Publishers, New York, N.Y.
|
| 26.
|
Glass, E. J., and P. Millar.
1994.
Induction of effective cross-reactive immunity by FMDV peptides is critically dependent upon specific MHC-peptide-T cell interactions.
Immunology
82:1-8[Medline].
|
| 27.
|
Hacket, C. J.,
D. Horowitz,
M. Wysocka, and S. B. Dillon.
1992.
Influenza virus infection elicits class II major histocompatibility complex-restricted T cells specific for an epitope identified in the NS1 non-structural protin.
J. Gen. Virol.
73:1339-1343[Abstract/Free Full Text].
|
| 28.
|
Hammerberg, C., and G. G. Schurig.
1986.
Characterization of monoclonal antibodies directed against swine leukocytes.
Vet. Immunol. Immunopathol.
11:107-121[CrossRef][Medline].
|
| 29.
|
Martínez-Salas, E.,
J. Ortín, and E. Domingo.
1985.
Sequence of the viral replicase gene from foot-and-mouth disease virus C1-Santa Pau (C-S8).
Gene
35:55-61[CrossRef][Medline].
|
| 30.
|
Mateu, M. G.
1995.
Antibody recognition of picornaviruses and escape from neutralization: a structural view.
Virus Res.
38:1-24[CrossRef][Medline].
|
| 31.
|
Mateu, M. G.,
M. L. Valero,
D. Andreu, and E. Domingo.
1996.
Systematic replacement of amino acid residues within an Arg-Gly-Asp-containing loop of foot-and-mouth disease virus and effect on cell recognition.
J. Biol. Chem.
271:12814-12819[Abstract/Free Full Text].
|
| 32.
|
Merrifield, R. B.
1963.
Solid phase synthesis. I. The synthesis of a tetrapeptide.
J. Am. Chem. Soc.
85:2149-2154[CrossRef].
|
| 33.
|
Milich, D. R.,
A. McLachlan,
G. B. Thornton, and J. L. Hughes.
1987.
Antibody production to the nucleocapsid and envelope of the hepatitis B virus primed by a single synthetic T-cell site.
Nature
329:547-549[CrossRef][Medline].
|
| 34.
|
Newman, J. F. E.,
P. G. Piatti,
B. M. Gorman,
T. G. Burrage,
M. D. Ryan,
M. Flint, and F. Brown.
1994.
Foot-and-mouth disease virus particles contain replicase protein 3D.
Proc. Natl. Acad. Sci. USA
91:733-737[Abstract/Free Full Text].
|
| 35.
|
Pescovitz, M. D.,
J. R. Thistlethwaite, Jr.,
H. Auchincloss, Jr.,
S. T. Ildstad,
T. G. Sharp,
R. Terrill, and D. H. Sachs.
1984.
Effect of class II antigen matching on renal allograft survival in miniature swine.
J. Exp. Med.
160:1495-1508[Abstract/Free Full Text].
|
| 36.
|
Pereira, H. G.
1981.
Foot-and-mouth disease, p. 333-363.
In
E. P. J. Gibbs (ed.), Virus disease of food animals. Academic Press, Inc., New York, N.Y.
|
| 37.
|
Porter, A. G.
1993.
Picornavirus nonstructural proteins: emerging roles in virus replication and inhibition of host cell functions.
J. Virol.
67:6917-6921[Free Full Text].
|
| 38.
|
Rodríguez, A.,
J. Dopazo,
J. C. Sáiz, and F. Sobrino.
1994.
Immunogenicity of nonstructural proteins of foot-and-mouth disease virus: differences between infected and vaccinated swine.
Arch. Virol.
136:123-131[CrossRef][Medline].
|
| 39.
|
Rodríguez, A.,
J. C. Sáiz,
I. S. Novella,
D. Andreu, and F. Sobrino.
1994.
Antigenic specificity of porcine T cell response against foot-and-mouth disease virus structural proteins: identification of T helper epitopes in VP1.
Virology
205:24-33[CrossRef][Medline].
|
| 40.
|
Rodríguez, A.,
J. C. Sáiz, and F. Sobrino.
1995.
In vitro synthesis of foot-and-mouth disease virus specific antibodies by porcine leukocytes.
Arch. Virol.
140:1645-1652[CrossRef][Medline].
|
| 41.
|
Rowlands, D. J.
1994.
Experimental determination of immunogenic sites, p. 137-168.
In
B. H. Nicholson (ed.), Synthetic vaccines. Blackwell Scientific Publications, Oxford, England.
|
| 42.
|
Rueckert, R. R.
1985.
Picornaviruses and their replication, p. 705-738.
In
B. N. Fields, D. P. Knipe, R. M. Chanoc, J. L. Melnick, B. Roizmann, and R. E. Shope (ed.), Fields virology. Raven Press, New York, N.Y.
|
| 43.
|
Russell, S. M., and F. Y. Liew.
1979.
T cells primed by influenza virion internal components can cooperate in the antibody response to haemagglutinin.
Nature
280:147-148[CrossRef][Medline].
|
| 44.
|
Ryan, M. D.,
G. J. Belsham, and A. M. Q. King.
1989.
Specificity of enzyme-substrate interactions in foot-and-mouth disease virus polyprotein processing.
Virology
173:35-45[CrossRef][Medline].
|
| 45.
|
Sáiz, J. C.,
A. Rodríguez,
M. González,
F. Alonso, and F. Sobrino.
1992.
Heterotypic lymphoproliferative response in pigs vaccinated with foot-and-mouth disease virus. Involvement of isolated capsid proteins.
J. Gen. Virol.
73:2601-2607[Abstract/Free Full Text].
|
| 46.
|
Sanz-Parra, A.,
M. A. Jimenez-Clavero,
M. M. García-Briones,
E. Blanco,
F. Sobrino, and V. Ley.
1999.
Recombinant viruses expressing the foot-and-mouth disease virus capsid precursor polypeptide (P1) induce cellular but not humoral antiviral immunity and partial protection in pigs.
Virology
259:129-134[CrossRef][Medline].
|
| 47.
|
Saw, D. M.,
C. M. Stanley,
C. D. Partidos, and M. Steward.
1993.
Influence of the T-helper epitope on the titer and affinity of antibodies to B-cell epitopes after coimmunization.
Mol. Immunol.
30:961-968[CrossRef][Medline].
|
| 48.
|
Sobrino, F.,
E. Blanco,
M. M. García-Briones, and V. Ley.
1999.
Synthetic peptide vaccines: foot-and-mouth disease virus as a model.
Dev. Biol. Stand.
101:39-43[Medline].
|
| 49.
|
Strebel, K.,
E. Beck,
K. Strohmaier, and H. Schaller.
1986.
Characterization of foot-and-mouth disease virus gene products with antisera against bacterially synthesized proteins.
J. Virol.
57:983-991[Abstract/Free Full Text].
|
| 50.
|
Summerfield, A.,
H.-J. Rziha, and A. Saalmüller.
1996.
Functional characterization of porcine CD4+ CD8+ extrathymic T lymphocytes.
Cell. Immunol.
168:291-296[CrossRef][Medline].
|
| 51.
|
Taboga, O.,
C. Tami,
E. Carrillo,
J. I. Núnez,
A. Rodríguez,
J. C. Sáiz,
E. Blanco,
M. L. Valero,
X. Roig,
J. A. Camarero,
D. Andreu,
M. G. Mateu,
E. Giralt,
E. Domingo,
F. Sobrino, and E. L. Palma.
1997.
A large-scale evaluation of peptide vaccines against foot-and-mouth disease: lack of solid protection in cattle and isolation of escape mutants.
J. Virol.
71:2606-2614[Abstract].
|
| 52.
|
Tam, J. P.,
W. F. Heath, and R. B. Merrifield.
1983.
SN2 deprotection of synthetic peptides with a low concentration of HF in dimethyl sulfide: evidence and application in peptide synthesis.
J. Am. Chem. Soc.
105:6442-6455[CrossRef].
|
| 53.
|
Toja, M.,
C. Escarmís, and E. Domingo.
1999.
Genomic nucleotide sequence of a foot-and-mouth disease virus clone and its persistent derivatives. Implications for the evolution of viral quasispecies during a persistent infection.
Virus Res.
64:161-171[CrossRef][Medline].
|
| 54.
|
Van Bekkum, J. G.
1969.
Correlation between serum antibody level and protection against challenge with FMD, p. 38-41.
In
Session of Research Group of the Standing Technical Committee of the European Commission for the Control of FMD, Brescia, Italy. Food and Agriculture Organization, Rome, Italy.
|
| 55.
|
Van Lierop, M. J.,
J. P. Wagenaar,
J. M. van Noort, and E. J. Hensen.
1995.
Sequences derived from the highly antigenic VP1 region 140 to 160 of foot-and-mouth disease virus do not prime for a bovine T-cell response against intact virus.
J. Virol.
69:4511-4514[Abstract].
|
| 56.
|
Vignali, D. A., and J. L. Strominger.
1994.
Amino acid residues that flank core peptide epitopes and the extracellular domains of CD4 modulate differential signaling through the T cell receptor.
J. Exp. Med.
179:1945-1956[Abstract/Free Full Text].
|
| 57.
|
Zinkernagel, R. M.
1996.
Immunology taught by viruses.
Science
271:173-178[Abstract].
|
| 58.
|
Zuckermann, F. A., and R. J. Husmann.
1996.
Functional and phenotypic analysis of porcine peripheral blood CD4/CD8 double positive T cells.
Immunology
87:500-512[Medline].
|
| 59.
|
Zuckermann, F. A.
1999.
Extrathymic CD4/CD8 double positive T cells.
Vet. Immunol. Immunopathol.
72:55-66[CrossRef][Medline].
|
Journal of Virology, April 2001, p. 3164-3174, Vol. 75, No. 7
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.7.3164-3174.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Juleff, N., Windsor, M., Lefevre, E. A., Gubbins, S., Hamblin, P., Reid, E., McLaughlin, K., Beverley, P. C. L., Morrison, I. W., Charleston, B.
(2009). Foot-and-Mouth Disease Virus Can Induce a Specific and Rapid CD4+ T-Cell-Independent Neutralizing and Isotype Class-Switched Antibody Response in Naive Cattle. J. Virol.
83: 3626-3636
[Abstract]
[Full Text]
-
Cubillos, C., de la Torre, B. G., Jakab, A., Clementi, G., Borras, E., Barcena, J., Andreu, D., Sobrino, F., Blanco, E.
(2008). Enhanced Mucosal Immunoglobulin A Response and Solid Protection against Foot-and-Mouth Disease Virus Challenge Induced by a Novel Dendrimeric Peptide. J. Virol.
82: 7223-7230
[Abstract]
[Full Text]
-
Guzman, E., Taylor, G., Charleston, B., Skinner, M. A., Ellis, S. A.
(2008). An MHC-restricted CD8+ T-cell response is induced in cattle by foot-and-mouth disease virus (FMDV) infection and also following vaccination with inactivated FMDV. J. Gen. Virol.
89: 667-675
[Abstract]
[Full Text]
-
Carrillo, C., Tulman, E. R., Delhon, G., Lu, Z., Carreno, A., Vagnozzi, A., Kutish, G. F., Rock, D. L.
(2005). Comparative Genomics of Foot-and-Mouth Disease Virus. J. Virol.
79: 6487-6504
[Abstract]
[Full Text]
-
Armengol, E., Wiesmuller, K.-H., Wienhold, D., Buttner, M., Pfaff, E., Jung, G., Saalmuller, A.
(2002). Identification of T-cell epitopes in the structural and non-structural proteins of classical swine fever virus. J. Gen. Virol.
83: 551-560
[Abstract]
[Full Text]
Top
Abstract
Introduction
