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Journal of Virology, December 2000, p. 11574-11580, Vol. 74, No. 24
Division of Infectious Diseases, Children's
Hospital Medical Center, Cincinnati, Ohio
45229,1 and Department of
Microbiology and Immunology, Tulane University Medical Center, New
Orleans, Louisiana 701122
Received 8 May 2000/Accepted 25 September 2000
The purpose of this study was to determine which regions of the VP6
protein of the murine rotavirus strain EDIM are able to elicit
protection against rotavirus shedding in the adult mouse model
following intranasal (i.n.) immunization with fragments of VP6 and a
subsequent oral EDIM challenge. In the initial experiment, the first
(fragment AB), middle (BC), or last (CD) part of VP6 that was
genetically fused to maltose-binding protein (MBP) and expressed in
Escherichia coli was examined. Mice (BALB/c) immunized with
two 9-µg doses of each of the chimeras and 10 µg of the mucosal adjuvant LT(R192G) were found to be protected against EDIM shedding (80, 92, and nearly 100% reduction, respectively; P Rotavirus infections are the primary
cause of severe gastroenteritis in young children and are the cause of
nearly one million deaths worldwide each year (3, 20, 32).
Several rotavirus vaccine candidates have been evaluated in clinical
trials with various degrees of success. All have been live, attenuated
rotavirus strains that are delivered orally to mimic the excellent
protection normally associated with natural rotavirus infection
(4, 5, 13, 17, 18, 24-26, 30). The most studied of these
vaccine candidates (Rotashield) consistently provided approximately
50% protection against all rotavirus diarrhea and 75% protection
against severe rotavirus disease (5, 17, 18, 26). In 1998, this vaccine was recommended for routine childhood immunization in the
United States but was withdrawn in less than 1 year after being
associated with intussusception, a rare form of bowel blockage found
most frequently in young children (9). Although it is unknown why Rotashield increased the risk of intussusception, all
future rotavirus vaccine candidates are expected to be even more
carefully scrutinized prior to their general usage.
To minimize possible association with intussusception, nonreplicating
rotavirus vaccine candidates represent an obvious alternative. In 1990, we developed an adult mouse model with which to evaluate possible novel
rotavirus vaccines (33). Using this model, we recently
immunized BALB/c and B-cell-deficient µMt mice intranasally (i.n.)
with an Escherichia coli-expressed chimeric protein
containing the rotavirus group antigen VP6 of murine rotavirus strain
EDIM (12). When challenged with EDIM, both strains of
immunized mice shed approximately 97% less rotavirus than did
unimmunized controls during the subsequent week. In µMt mice, this
excellent protection was not dependent upon anti-VP6 antibody because
these mice made no detectable rotavirus antibody following VP6
immunization. Protection was highly dependent on coadministration of
attenuated E. coli heat-labile toxin LT(R192G) as an
adjuvant. The possible usefulness of chimeric VP6 as a vaccine
candidate was enhanced by the observation that protection
remained constant for at least 3 months after immunization and equal
protection was induced by 1, 2, or 3 i.n. doses of this protein
(12).
Because of the potential for VP6 to be developed into a rotavirus
vaccine, it was of immediate interest to determine the
locations of the protective epitopes within the VP6 protein. Once these are identified, it may be possible to study the immune effector mechanisms they induce. At the same time, identification of protective epitopes within VP6 may advance the development of the subunit VP6
vaccine into peptide vaccines. The purpose of this study was to use
deletion mutant forms of VP6 and synthetic peptides to compare the
abilities of different regions of the VP6 protein to elicit protection
in the adult mouse model.
Virus.
The murine EDIM strain of rotavirus that was used
throughout this study was originally isolated from a fecal specimen of
an infected mouse (obtained from M. Collins, Microbiological
Associates, Bethesda, Md.). It was adapted to grow in cell culture by
serial passage in MA-104 cells, a monkey kidney-derived cell line.
After the ninth passage, the virus was triply plaque purified. This preparation was used for the construction of recombinant plasmids containing the entire VP6 gene or deletion mutant forms of VP6. Cell
culture-adapted EDIM (passage 9) was used to challenge mice after
immunization. This virus preparation had a titer of 107
focus-forming units (FFU)/ml.
Construction of recombinant pMAL-c2X plasmids.
The
bacterial expression plasmid pMAL-c2X (New England Biolabs,
Beverly, Mass.) was used to construct recombinant plasmids pMAL-c2X/EDIM6, pMAL-c2X/EDIM6AB,
pMAL-c2X/EDIM6BC, pMAL-c2X/EDIM6CD, pMAL-c2X/EDIM6CD1, pMAL-c2X/EDIM6CD2,
pMAL-c2X/EDIM6CD3, and pMAL-c2X/EDIM6CD4 containing VP6 or deletion mutant forms of VP6 (i.e., AB, BC, CD, CD1,
CD2, CD3, and CD4, respectively) using standard cloning procedures
(1). Briefly, cDNAs were synthesized by PCR using pcDNA1/EDIM6 (11) as the template and gene-specific primers (Table 1) and were inserted into the
XmnI restriction site of pMAL-c2X. The inserted sequences
were placed downstream from the E. coli malE gene, which
encodes the maltose-binding protein (MBP), and the factor Xa
proteolytic cleavage site (Ile-Glu-Gly-Arg). Recombinant pMAL-c2X
plasmids were transformed into BL21(DE3), a protease-deficient strain
of E. coli. Bacterial colonies containing deletion mutant
forms of VP6 were identified by blue-to-white selection.
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Functional Mapping of Protective Domains and
Epitopes in the Rotavirus VP6 Protein
ABSTRACT
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
0.01) following challenge. Because CD produced almost complete
protection, we prepared four E. coli-expressed, MBP-fused
chimeras containing overlapping fragments of the CD region (i.e., CD1,
CD2, CD3, and CD4) whose lengths ranged from 61 to 67 amino acid
residues. Following i.n. immunization, CD1, CD2, and CD4 induced
significant (P 0.004) protection (88, 84, and 92%
reduction, respectively). In addition, 11 peptides (18 to 30 residues)
of the CD region with between 0 and 13 overlapping amino acids were
synthesized. Two 50-µg doses of each peptide with LT(R192G) were
administered i.n. to BALB/c mice. Five peptides were found to elicit
significant (P 0.02) protection. Moreover, a
14-amino-acid region within peptide 6 containing a putative
CD4+ T-cell epitope was found to confer nearly complete
protection, suggesting a protective role for CD4+ T cells.
Mice that were protected by fragments BC and CD1 and four of the five
protective synthetic peptides did not develop measurable rotavirus
antibodies in serum or stool, implying that protection induced by these
domains was not dependent on antibody. Together, these observations
suggest that multiple regions of VP6 can stimulate protection, a region
of VP6 as small as 14 amino acids containing a CD4+ T-cell
epitope can stimulate nearly complete protection, and protection
mediated by a subset of epitopes in the VP6 protein does not require
antibodies in BALB/c mice.
INTRODUCTION
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
TABLE 1.
Oligonucleotide primers used in PCRs to construct
chimeric VP6 proteins
Induction of recombinant proteins.
Induction of expression
of MBP-based chimeric proteins was performed by the method of Jarrett
and Foster (16) as previously described (12). A
single colony of recombinant bacteria expressing each chimeric protein
was grown as an overnight culture (37°C) in 50 ml of rich broth (10 g
of tryptone per liter, 5 g of yeast extract per liter, 5 g of
NaCl per liter, 2 g of glucose per liter, 100 mg of ampicillin per
liter). On the following day, 10 ml of the overnight cell culture was
inoculated into 1 liter of rich broth. When the
A600 reached approximately 0.6, IPTG
(isopropyl-
-D-thiogalactopyranoside) was added to give a
final concentration of 0.3 mM to induce expression of chimeric
proteins. At 3 h postinduction, the cell suspension was
centrifuged (4,000 × g, 20 min, 4°C) to harvest the
cells, which were washed in phosphate-buffered saline and again
centrifuged. The supernatant was discarded, and the cell pellet was
frozen at 
20°C.
Preparation of soluble chimeric proteins by affinity
chromatography.
The procedure used to prepare chimeric VP6
proteins has been described elsewhere (12). In short, the
frozen bacterial pellets were thawed and resuspended in 50 ml of buffer
L (5 mM NaH2PO4, 10 mM
Na2HPO4, 30 mM NaCl, 10 mM -mercaptoethanol,
0.2% Tween 20, 200 mg of lysozyme per liter). After digestion (15 min,
room temperature), the suspensions were sonicated (Bronwill BioSonic IV, 50% power setting, three 30-s bursts; VWR Scientific, Piscataway, N.J.) in an ice-and-water bath. NaCl and RNase A (final concentrations of 26.5 mg/ml and 5 µg/ml, respectively) were then added. The lysates
were centrifuged (54,000 × g, 30 min) to separate
insoluble cell debris (which included inclusion bodies containing
insoluble chimeric VP6 protein) from supernatants (soluble fraction)
that contained soluble chimeric rotavirus proteins. Amylose resin was prepared by placing 25 ml of the packed resin (New England Biolabs) in
a 250-ml centrifuge tube and washing it twice with 8 volumes of buffer
C (buffer L containing 0.5 M NaCl). The mixture was rocked for 30 min
at 4°C, and the resin was recovered by centrifugation (2,100 × g, 5 min). The soluble fractions were mixed
with amylose resin for 2 h in a 500-ml flask on a magnetic
stirrer. After centrifugation (2,100 × g, 5 min), the
resin was recovered and then resuspended in 50 ml of buffer C, rocked
for 30 min, and centrifuged to recover the resin. The resin was washed
in this manner three times and finally washed overnight with 500 ml of
buffer C. On the following day, the resin was recovered by
centrifugation (2,100 × g, 5 min), resuspended in 50 ml of buffer D (50 mM Tris-HCl [pH 7.5], 50 mM NaCl, 1 mM EDTA, 10 mM
-mercaptoethanol), and rocked for 30 min. The resin was pelleted by
centrifugation (2,100 × g, 5 min), and the bound
fusion protein was eluted from the resin with 250 ml of 15 mM maltose
in buffer D for 2 h. The resin was removed by centrifugation
(2,100 × g, 5 min), and the buffer in the supernatant containing the fusion proteins was replaced with phosphate-buffered saline and simultaneously concentrated by ultrafiltration using a
stirred-cell concentrator (model 8400; Amicon Inc., Beverly, Mass.).
The concentration of preparations of chimeric VP6 protein or chimeric
VP6 fragments was maintained at 180 µg/ml (i.e., 9 µg/50-µl
dose), since further concentration led to gradual precipitation of the
purified proteins. Concentrations of purified proteins were measured by
the method described by Bradford (6).
Western blot analyses of chimeric rotavirus proteins.
Preparations of affinity chromatography purified chimeric VP6, AB, BC,
and CD proteins were subjected to sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE). Samples were suspended
in gel loading buffer (50 mM Tris [pH 6.8], 10% glycerol, 5% SDS,
5% -mercaptoethanol, 0.005% bromophenol blue), heated (95°C, 5 min), and subjected to SDS-PAGE. Following SDS-PAGE, separated
proteins were blotted to nitrocellulose sheets which were then blocked
with 5% skim milk in TBS (25 mM Tris-HCl [pH 7.5], 0.9% NaCl). The
sheets were then incubated with a rabbit anti-MBP serum (1:10,000
dilution; New England Biolabs). After washing with TTBS (0.1% Tween 20 in Tris-buffered saline [TBS]), the sheet was incubated with goat
anti-rabbit immunoglobulin G (IgG) conjugated to alkaline phosphatase
(1:3,000; Life Technologies, Gaithersburg, Md.). The sheet was washed
with TTBS and then incubated with 5-bromo-4-chloro-3-indolylphosphate
(BCIP; 0.25 mg/ml) and nitroblue tetrazolium (0.25 mg/ml; Life
Technologies) to visualize bound antibodies.
Western blot analyses of immune sera. To determine whether the immune sera obtained from mice vaccinated with chimeric deletion mutant form AB, BC, or CD of VP6 generated antibodies against the specific rotavirus proteins, triple-layered rotavirus particles were subjected to SDS-PAGE as described above. Following SDS-PAGE, separated rotavirus proteins were electrophoretically transferred to nitrocellulose sheets, which were cut into strips. The strips were blocked with 5% skim milk in TBS. The strips were then incubated with antisera obtained from mice immunized with chimeric VP6, AB, BC, or CD, which was used at a 1:100 dilution. After washing with TTBS, the strips were incubated with goat anti-mouse IgG conjugated to alkaline phosphatase. The strips were washed with TTBS and then incubated with nitroblue tetrazolium and BCIP to visualize bound antibodies as described above.
Synthetic peptides.
Peptide synthesis was performed by
Quality Control Biochemicals, Inc. (Hopkinton, Mass.), or by
Sigma-Genosys (The Woodlands, Tex.). The peptides designated 1 through
11 were derived from the amino acid sequence of the last half of VP6
(amino acids 197 to 397; Table 2). The
lengths of the peptides ranged from 18 to 30 residues, and the
overlapping sequences ranged from 0 to 13 residues in length. Peptide
6-14, a 14-amino-acid peptide contained within 25-amino-acid peptide 6, was also synthesized. The traditional solid-phase method of peptide
synthesis was employed utilizing orthogonally protected amino acids.
Cleavage and deprotection were performed with aqueous trifluoroacetic
acid in the presence of scavengers. The purity of the peptides was
greater than 95% according to mass spectral and reverse-phase
high-pressure liquid chromatography analyses.
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Mouse strains. Rotavirus antibody-free BALB/c mice were used in these studies. They were purchased from Harlan-Sprague-Dawley (Indianapolis, Ind.) when 6 weeks of age. All mice were housed in groups of three or four in sterile microisolation cages. All procedures were carried out in accordance with protocols reviewed and approved by the Children's Hospital Research Foundation Institutional Animal Care and Use Committee.
Immunization of mice with chimeric rotavirus proteins or synthetic peptides. Immunization of mice (i.n.) was carried out under light sedation, after placing them in a closed vessel with Metafane (methoxyflurane; Pitman-Moore, Inc., Mundelein, Ill.) until they could no longer stand, by administration of two 60-µl doses (30 µl per nostril) of immunogen separated by 2 weeks. In an earlier study (12), we found that one dose of 9 µg of chimeric MBP-VP6 in a 50-µl volume (i.e., 2 µM) was sufficient to induce 99.5% protection. Since priming followed by one or two boosts did not further stimulate the protection obtained with a single dose, it is not likely that increasing the antigen dose would improve protection higher than 99.5%. Nevertheless, to ensure maximum protection, a two-dose rather a one-dose regimen was implemented for all immunizations in the present study. In every case, each dose of immunogen consisted of 9 µg of one of the purified chimeric proteins or 50 µg of one of the synthetic peptides along with 10 µg (10 µl) of the attenuated E. coli heat-labile toxin LT(R192G) adjuvant in a 60-µl volume. The adjuvant LT(R192G) carries a mutation in the proteolytic site of its A subunit at amino acid 192 with the replacement of the arginine with a glycine residue. The mutation abrogates cleavage of LT(R192G) and attenuates the toxicity of the protein (14). To compare the protective efficacies of the chimeric AB, BC, and CD fragments, 9 µg (50 µl of 2.8 µM) of the chimeric AB, BC, or CD region of VP6 was used to inoculate mice. To compare the efficacies of the chimeric CD1, CD2, CD3, and CD4 fragments, 9 µg (50 µl of approximately 3.4 µM) of each chimeric fragment was used for immunization. To determine the peptides that could elicit protection, mice were inoculated with 50 µg (50 µl) with concentrations of each peptide ranging from 288 to 592 µM (see Table 6). In a previous study, we showed that immunization of mice with 10 µg of LT(R192G) alone did not produce rotavirus antibodies or stimulate protection (12).
Challenge of mice with EDIM rotavirus. Four weeks after the last immunization, mice were orally (gavage) challenged with 4 × 104 FFU (focus-forming units), which was equivalent to 100 50% shedding doses of passage 9 EDIM.
Detection of rotavirus antigen in stools. Two fecal pellets were collected from each mouse for 7 or more days following EDIM challenge and kept in 1 ml of Earle's balanced salt solution. Samples were stored frozen until analyzed, at which time they were homogenized and centrifuged (1,500 × g, 5 min, 4°C) to remove debris. Quantities of rotavirus antigen in the fecal samples were determined by enzyme-linked immunosorbent assay (ELISA) as nanograms per milliliter per specimen using methods already described (19).
Determination of rotavirus antibody titers. Blood samples were collected by retro-orbital capillary plexus puncture before the first immunization, before challenge, and 3 weeks after challenge. Stool specimens were collected at the same periods. Titers of rotavirus IgG and IgA in serum, as well as fecal rotavirus IgA, were determined by ELISA using EDIM lysate as the antigen as previously described (12, 19).
Statistical methods.
Statistical analyses of differences in
the amounts of shed rotavirus antigen and titers of rotavirus-specific
antibodies between groups of mice immunized with different chimeric
proteins or synthetic peptides and mock-vaccinated groups were
performed by Students t test (analysis of variance).
Differences between groups were considered significant when the
probability (P) level was 0.05.
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Protective epitopes are present in the first, middle, and last parts of VP6. Three plasmids that expressed large overlapping recombinant proteins encompassing the entire VP6 molecule were constructed to determine the locations of protective epitopes in VP6. These recombinant plasmids, which were constructed by deleting portions of the VP6 gene, expressed approximately the first (amino acids 1 to 196; fragment AB), middle (amino acids 97 to 299; fragment BC), and last (amino acids 197 to 397; fragment CD) parts of VP6. The gene sequences encoding these VP6 fragments were cloned into plasmid pMAL/c2X. They were then expressed in E. coli as chimeric proteins with the carboxyl terminus of MBP, encoded by the plasmid, genetically fused to the amino terminus of the protein fragments. The chimeric proteins were purified by affinity chromatography using amylose resin and analyzed by Western blotting as described for chimeric VP6 (12). Polypeptides migrating with the expected mobility of chimeric fragments AB (65.2 kDa), BC (66.1 kDa), and CD (65.14 kDa) were detected. As in the case of chimeric VP6 (12), truncated MBP-containing polypeptides were also obtained even though the proteins were expressed in a protease-deficient strain of E. coli. Furthermore, the amount of truncated products was equivalent for each of the expressed chimeric protein, as determined by Western blot analysis (results not shown).
To determine whether any of these VP6 fragments, i.e., VP6 deletion mutant proteins, contained protective epitopes, groups of BALB/c mice were immunized i.n. with two 9-µg inoculations of chimeric VP6 fragments (50 µl of 2.8 µM) or unmodified VP6 protein (50 µl of 2 µM). In every case, 10 µg of the mucosal adjuvant LT(R192G) was included in the inoculum. The mice were then orally challenged with live murine rotavirus strain EDIM 4 weeks after the second immunization. Stool specimens were collected from the immunized and mock-immunized groups between 1 and 7 days after challenge. The quantities of rotavirus antigen in the stools were measured by ELISA. The protective efficacy of each VP6 fragment was calculated as the reduction in rotavirus shedding in each immunized group relative to the mock-immunized group. Mice immunized with each of the VP6 fragments (i.e., AB, BC, or CD) were protected against EDIM shedding (P 0.01, Table
3). However, reductions in shedding in
the groups immunized with fragments AB and BC (79.4 and 92.5%,
respectively) were significantly (P 0.005) less than that in the CD-immunized group (99.8%). Therefore, protective epitopes were present in all three VP6 fragments but the CD
fragment elicited the best protection.
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Fragment BC does not induce detectable rotavirus antibody. The largest antibody responses following rotavirus infection have been consistently against the VP6 protein (12). Furthermore, i.n. immunization with chimeric VP6 was found to induce high ELISA titers of serum rotavirus antibodies (12). Although it was subsequently observed that protection following VP6 immunization appeared not to depend on antibody (12), it was still of interest to determine whether rotavirus antibody responses were stimulated by each of the three VP6 fragments and whether these responses correlated in any way with the protection elicited by the fragments.
To make this determination, blood and stool specimens collected 4 weeks after the second i.n. immunization (the day prior to challenge) were analyzed for rotavirus antibodies by ELISA. As previously reported, chimeric VP6 administered with LT(R192G) elicited high titers of rotavirus IgG in serum, moderate titers of rotavirus IgA in serum, and very low titers of rotavirus IgA in stool (12; Table 4). Fragment CD induced significantly higher titers of rotavirus IgG and IgA in serum, and rotavirus IgA in stool than did fragment AB (P 0.01). Unexpectedly,
none of the mice administered fragment BC developed rotavirus antibody
detectable by ELISA in serum or stool. To verify that rotavirus
antibody generated in BC-immunized mice was not detectable merely due
to its inability to bind to VP6 contained in the EDIM lysate used in
the ELISA, Western blot analysis was performed using antisera collected
from the VP6-, AB-, BC-, and CD-immunized groups. In this assay, the
antibody must recognize denatured rather than native VP6. Again,
rotavirus antibody was readily detected in mice immunized with VP6 or
its AB and CD fragments but not in the BC-immunized animals (data not
shown). Since BC stimulated nearly complete protection, this result
demonstrates that antibody was not absolutely required for protection
of mice immunized with a VP6 fragment. Clearly, therefore, ELISA
antibody titers can only be used as markers of protection following
i.n. immunization with VP6 or the AB and CD fragments.
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Mapping of protective domains within the CD fragment of VP6.
Since the CD region was found to elicit the best protection of the VP6
fragments, this portion of VP6 was further analyzed for protective
epitopes. To delineate the distribution of protective epitopes
within this region, we first constructed four deletion mutant proteins
containing overlapping fragments within the CD region. These deletion
mutant proteins, which were designated CD1 (amino acids 197 to 263),
CD2 (amino acids 244 to 310), CD3 (amino acids 291 to 351), and CD4
(amino acids 332 to 397) were 67, 67, 61, and 65 residues in length.
Again, these VP6 fragments were expressed in E. coli as
chimeric proteins with the VP6 regions fused to the carboxyl terminus
of MBP. Following two 9-µg i.n. immunizations [50 µl of 3.4 µM
with 10 µg of LT(R192G)] separated by a 2-week interval, the mice
were orally challenged with EDIM. Fragments CD1, CD2, CD3, and CD4
induced 88, 84, 19, and 92% reductions in shedding, respectively
(Table 5). The reductions induced by CD1,
CD2, and CD4 were all found to be significant (P 0.004), but protection induced by fragment CD4 was not
significantly better than that induced by CD1 (P = 0.053) and CD2 (P = 0.057). ELISA titers of
rotavirus antibodies were again measured to determine whether there was
any association between rotavirus antibodies and protection. Fragments
CD1 and CD3 were found not to induce antibodies, while CD2 and CD4
induced high titers of rotavirus IgG in serum (data not shown).
Therefore, no association between rotavirus antibodies and protection
was obtained with fragment CD1.
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0.02) reductions in EDIM shedding during the 7 days following challenge (Table 6). These
peptides reduced shedding between 57 and 93%, clearly indicating that
regions of VP6 with as few as 18 amino acids could stimulate good
protection in this model. In a subsequent experiment, the effective
antigen doses for two of these peptides were examined. It was found
that reduction of antigen doses to 10 or 2 µg for peptide 3 or 6 induced the same level of protection obtained with 50 µg (results not shown). Therefore, the difference in protection observed with each
peptide was not likely due to administration of suboptimal antigen
doses.
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Protection against rotavirus shedding is induced by i.n. immunization with a VP6 peptide containing a putative CD4+ T-cell epitope. Porcine rotavirus strain YM has been reported (2) to contain a CD4+ T-cell epitope for BALB/c mice within a 14-amino-acid region of VP6 (i.e., amino acids 289 to 302). The same region of EDIM VP6 with nearly the same sequence is contained within 25-amino-acid synthetic peptide 6 (i.e., RLSFQLMRPPNMTP), where the first methionine replaces a valine residue in the YM strain. Furthermore, peptide 6 stimulated good protection against EDIM shedding following i.n. immunization of BALB/c mice (Table 6). Because CD4+ T cells may be effectors of protection in this model, the 14-amino-acid peptide containing the putative CD4+ T-cell epitope was synthesized and used for i.n. immunization of BALB/c mice. Two 50-µg doses (50 µl of 592 µM) of this 14-mer peptide (peptide 6-14) stimulated between 93 and 98% reductions in EDIM shedding in three separate experiments (Table 6). This result established that a region of VP6 consisting of only 14 amino acids is sufficient to stimulate protection and suggests that CD4+ T cells are at least one of the effectors of protection stimulated by i.n. immunization with VP6.
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DISCUSSION |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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We recently reported that i.n. immunization of mice with an E. coli-expressed chimera composed of MBP and the VP6 protein of murine rotavirus strain EDIM (i.e., MBP-VP6) stimulated nearly complete protection against shedding following subsequent oral challenge with live EDIM. Protection was dependent on inclusion of a mucosal adjuvant during immunization, and the adjuvant utilized for most studies was the attenuated E. coli heat-labile toxin LT(R192G). Based on the possibility that results obtained with the VP6 protein in this mouse model may be useful in the development of a human rotavirus vaccine, it was of interest to determine what regions of the VP6 protein stimulate protection. This information should not only be useful in uncovering the mechanism of protection but also help define regions of VP6 that might be included as a possible peptide vaccine.
The study plan was to compare the abilities of different regions of the
VP6 protein to stimulate protection in BALB/c mice as the sizes of
these regions were gradually reduced. The results of this study are
summarized in Fig. 1. Although the first,
middle, and last parts of VP6 each stimulated excellent protection in this model, the last 50% (i.e., the CD region) was significantly (P < 0.001) more protective than the first 50% (i.e.,
the AB region) of this protein. When the protective epitopes within
the CD region were further delineated using two sets of either four
overlapping protein fragments or 11 overlapping synthetic peptides,
both protective and nonprotective regions were identified. Fragments
CD1, CD2, and CD4 were all protective, while CD3 was not. Immunization
with the 11 peptides provided even more definitive data. Five of those peptides contained epitopes that stimulated significant protection, while six did not. Because peptides 2 and 3 contained 11 overlapping residues which were of sufficient length to harbor a major
histocompatibility complex (MHC)-binding epitope (7, 10, 22,
23, 27), it is not certain whether the two peptides contain
distinct protective epitopes or share a common epitope.
Similarly, it is uncertain whether peptides 3 and 4 share a common
epitope. Since peptides 2 and 4 do not share common sequences, at
least two epitopes are located in the region spanned by these three
peptides.
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Peptide 6 was also found to be protective (74 to 93%) and contained a 14-amino-acid sequence (amino acids 289 to 302) that was almost identical to the one found in VP6 of the porcine YM strain of rotavirus (2). The porcine sequence was reported to contain an epitope that could recognize CD4+ T-cell hybridomas in the context of an MHC class II IEd molecule. Interestingly, the EDIM VP6-derived 14-mer synthetic peptide was found to induce excellent protection (93 to 98%). Therefore, we have located a very small region of VP6 that can stimulate almost complete protection. The binding groove of the MHC class II molecule is open at both ends, allowing naturally processed peptides of various lengths (10 to 30 residues) to bind within the groove (10, 22). The peptides that bind class II molecules have a core binding region of 9 amino acids with certain key pockets in the groove accommodating peptide side chains in a fashion similar to that of the class I molecules (7, 15, 22, 27). Because the core peptides appear to be as small as nine residues in length, it will be of interest to determine whether smaller MHC class II-binding epitopes can be further identified in this 14-amino-acid region.
Fragments CD2 and CD4 induced high titers of rotavirus antibodies, whereas detectable titers of antibodies were induced by only two synthetic peptides (peptides 1 and 3). The poor humoral responses obtained with the synthetic peptides were not unexpected, because most small peptides by themselves do not stimulate B-cell responses. To increase immunogenicity, peptides containing B-cell epitopes are often coupled to carrier proteins containing T-cell epitopes (21, 28). A number of studies have found that synthesis of T-cell epitopes contiguous with B-cell epitopes also increases the immunogenicity of the B-cell epitopes (8, 31).
The extraordinary magnitude of protection afforded by the 14-amino-acid stretch of VP6 might be mediated by the reported CD4+ T-cell epitope alone and not require epitopes such as those recognized by specific immunoglobulin receptors on B cells. This contention is supported by the observation (12) that B-cell-deficient µMt mice were fully protected following i.n. immunization with MBP-VP6. Thus, antibody was not required for protection in these mice. It should be noted that µMt mice belong to the H-2b haplotype, while BALB/c mice, which were used in this study with the 14-mer peptide, belong to the H-2d haplotype. Therefore, the results obtained in studies using µMt mice may not be directly applicable to mice having different haplotypes. Nevertheless, fragments BC and CD1 of VP6, as well as several peptides of VP6, stimulated good protection in BALB/c mice but induced no detectable rotavirus antibody in these mice. These results reinforce the hypothesis that antibody is not required for protection following i.n. immunization with VP6 or its peptides in BALB/c mice and, possibly, any mouse strain. It also establishes that antibody titers cannot be used as reliable markers of immunity, at least following i.n. immunization with some of the VP6 deletion mutant polypeptides or synthetic peptides.
It should be noted that 100% congruity was found between regions of CD
that elicited significant (P 0.05) protection using the four CD fragments and the 11 synthetic peptides. That is, the only
fragment that was not significantly protective was CD3 and this
fragment contained only nonprotective peptides 7 and 8 in their
entirety. Furthermore, the three protective fragments (CD1, CD2 and
CD4) all contained at least one complete protective synthetic peptide.
Two other interesting features of CD3 should also be noted. The first
is that peptide 8, which CD3 contained in its entirety, stimulated 51%
protection. Although that was not significant (P = 0.07) by our criterion, it was marginally so. Peptide 8 was
difficult to synthesize and was therefore modified by deletion of the
glycine residue at position 321. Had this glycine residue been present,
peptide 8 might have been either more or less protective. Had the
former occurred and the authentic peptide 8 actually stimulated
significant protection, there would have been a lack of congruity
between the protection stimulated by CD3 and peptide 8, possibly due to
improper processing of CD3 for antigen presentation. The second feature
of interest is that CD3 contained 17 of the 25 amino acid residues
within protective peptide 6, including 12 of the 14 residues in
protective peptide 6-14. Since CD3 lacks only the first two amino acids
of the 14-mer peptide, it appeared likely that these two residues are
critical for this peptide to stimulate protection. This possibility
will be further examined through truncation studies with the 14-mer peptide.
From the results presented, it is clear that multiple regions of VP6 can stimulate protection against rotavirus shedding in adult BALB/c mice following i.n. immunization. Since so many regions of VP6 can elicit protection in H-2d mice, it is likely that all haplotypes of adult mice will be protected by responses against at least some regions of this protein. As already noted (12), both H-2b (µMt) and H-2d (BALB/c) mice are equally protected following i.n. immunization with VP6. Taking this a step further, if VP6 is eventually found to stimulate immunity against disease in humans following immunization by this route, it follows that persons of many, if not all, HLA types may be protected. Finally, because VP6 is a very conserved protein among group A rotaviruses, with generally >90% homology at the amino acid level (29), immunization with VP6 from any group A rotavirus strain may protect against all group A rotaviruses. These possibilities need to be verified, but if they are shown to be true, VP6 may constitute a highly effective vaccine against rotavirus.
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ACKNOWLEDGMENT |
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This work was funded in part by NIH-NIAID contract NO1 AI 45252, which was awarded to the Children's Hospital Medical Center, Cincinnati, Ohio.
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FOOTNOTES |
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* Corresponding author. Mailing address: Division of Infectious Diseases, Children's Hospital Medical Center, 3333 Burnet Ave., Cincinnati, OH 45229-3039. Phone: (513) 636-7679. Fax: (513) 636-7655. E-mail: anthony.choi{at}chmcc.org.
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REFERENCES |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Journal of Virology, December 2000, p. 11574-11580, Vol. 74, No. 24
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