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Journal of Virology, April 1999, p. 2854-2862, Vol. 73, No. 4
Department of Zoology, The University of Hong
Kong, Pokfulam, Hong Kong, China
Received 29 September 1998/Accepted 4 January 1999
The full-length RNA genomes of a chicken embryonic fibroblast
(CEF)-nonpermissive, very virulent infectious bursal disease virus
(IBDV) (strain HK46) were amplified into cDNAs by reverse transcription-PCR. The full-length cDNAs were sequenced and subcloned into a eukaryotic expression vector, from which point mutations were
introduced into the VP2 region by site-directed mutagenesis. The
wild-type and mutated plasmids were transfected directly into CEFs to
examine their ability to generate CEF-permissive recombinant viruses.
Substitution of amino acid residues 279 (Asp Infectious bursal disease (IBD),
mediated by infectious bursal disease virus (IBDV), causes significant
losses to the poultry industry. IBDV multiplies rapidly in developing B
lymphocytes in the bursa of Fabricius, leading to immunosuppression and
increased susceptibility to other diseases. Two distinct serotypes of
IBDV, serotype 1 and serotype 2, have been identified. Serotype 1 strains are pathogenic to chickens and vary in virulence, whereas
serotype 2 strains isolated from turkeys are apathogenic for both
turkeys and chickens. Serotype 1 strains can be further subdivided into four groups: classical virulent strains, attenuated strains, antigenic variant strains, and very virulent strains. Classical virulent strains
cause bursal inflammation and severe lymphoid necrosis in infected
chickens, resulting in immunodeficiency and moderate mortality (20 to
30% in specific-pathogen-free [SPF] chickens). Antigenic variant
strains are recognized by the ability to escape cross-neutralization by
antisera against classical strains. Chickens affected by the variant
strains are characterized by severe atrophy of the bursa without
showing the inflammation associated with infection by classical strains
(13). Attenuated strains are generated by adapting the
classical and variant strains to chicken embryo fibroblast (CEF) cells
or other cell lines through serial passages. They do not cause diseases
in chickens, and therefore some of them are being used as live
vaccines. Since the late eighties, outbreaks of newly evolved, very
virulent strains in Europe, Japan, and China have caused significant
economic losses to the poultry industry. Very virulent strains can
break through high levels of maternal antibody and cause up to 60 to
100% mortality in SPF birds. These strains cause lesions typical of
IBDV and are antigenically similar to the classical strains
(3).
IBDV is a member of the Birnaviridae family, as its genome
consists of two segments of double-stranded RNA (dsRNA). Genome segment
B (2.8 kb) encodes VP1, a 90-kDa multifunctional protein with
polymerase and capping enzyme activities (6). Genome segment A (3.2 kb), encodes a polyprotein that is cleaved by autoproteolysis to
form mature viral proteins VP2, VP3, and VP4, of which VP2 is the major
host-protective immunogen of IBDV that contains the antigenic regions
responsible for induction of neutralizing antibodies (2). A
second open reading frame, preceding and partially overlapping the
polyprotein gene, encodes VP5, a 17-kDa polypeptide present in
IBDV-infected cells. However, the function of the polypeptide is still
unknown (7, 19).
Seven IBDV strains isolated from China have recently been characterized
(3), including a classical strain, CJ801; an attenuated strain, GZ911; a variant strain, GZ902; and four very virulent strains,
G9201, G9302, F9502, and HK46. CJ801 has the greatest identity to the
classical strains STC and 52/70, whereas GZ902 has the greatest
identity to the American variant strains A, E, and GLS. Attenuated
strain GZ911, like other cell culture-adapted strains, has
substitutions at positions 279 (D to N) and 284 (A to T) as well as in
the serine-rich heptapeptide region. Hence, these substitutions may
play an important role in the reduced virulence of these strains. The
four very virulent strains have the greatest identity with the European
very virulent strain UK661 (2) and Japanese strain OKYM
(18). They share unique amino acid residues at positions
222A, 256I, and 294I, which are not present in other, less virulent strains.
A method of generating virus by transfecting cRNA of the CEF-adapted
strain D78 into Vero cells has recently been reported (9).
However, there is no report on using similar technology to convert a
CEF-nonpermissive IBDV strain into a CEF-permissive strain. In this
study, we have cloned the full-length cDNA of a CEF-nonpermissive, very
virulent IBDV strain in which certain substitutions were introduced
into the cDNA by site-directed mutagenesis. By directly transfecting
the modified cDNAs, instead of cRNAs, into CEFs, a CEF-permissive
recombinant virus was generated from the very virulent IBDV strain.
Viruses and cells.
CEF cells were prepared from 10-day-old
SPF eggs (Beijing Merial Vital Laboratory Animal Technology) and
maintained in Dulbecco modified Eagle medium with 5% (vol/vol) fetal
bovine serum and 10% (wt/vol) tryptose phosphate broth
(17). CEF-adapted strain D78 (ATCC VR-2047), as well as the
recombinant viruses generated by reverse genetics, were propagated in
secondary CEF. The classical strains CJ801 and G9219 and the very
virulent strains HK46, G9201, G9303, and F9502 were propagated in SPF
chickens at 5 weeks of age.
Purification of IBDV from bursa and extraction of viral RNA.
Bursas from SPF birds infected by HK46 were removed and homogenized in
TNE buffer (10 mM Tris-HCl, 100 mM NaCl, 1 mM EDTA [pH 8.0]) at a
ratio of 1 g of bursa to 10 ml of TNE buffer. After freezing and
thawing three times, homogenates were centrifuged at 17,000 × g for 15 min at 4°C, and the supernatant was collected for
virus purification. One milliliter of bursal homogenate supernatant was
loaded onto 4 ml of a 40% sucrose cushion and ultracentrifuged at
55,000 × g (Beckman sw55Ti rotor, 22,000 rpm) for
2.5 h at 4°C. After removal of the cushion, pelleted IBDV
particles were resuspended in proteinase K buffer (TNE plus 0.5%
[wt/vol] sodium dodecyl sulfate), digested with 1 mg of proteinase K
per ml for 1 h at 37°C, and extracted twice with
phenol-chloroform-isoamylalcohol (25:24:1, vol/vol/vol). Finally, the
viral dsRNAs were precipitated from the upper aqueous phase by ethanol.
Construction of full-length cDNA clones.
The cDNAs of IBDV
segments A and B of the very virulent strain HK46 were synthesized
separately. Two primer pairs (Table 1), designated A5-A3 and B5-B3, were used for synthesizing segment A and B
cDNAs, respectively. Viral dsRNAs mixed with primers A5 and A3 (for
segment A) or B5 and B3 (for segment B) were denatured by boiling for 5 min and cooled on ice for 2 min. First-strand cDNAs were synthesized as
described previously (3). All primers used for PCR and
mutagenesis are listed in Table 1. Four fragments, designated FA5 (5'
end fragment of segment A), FA3 (3' end fragment of segment A), FB5 (5'
end fragment of segment B), and FB3 (3' end fragment of segment B),
were independently amplified by the Expand High Fidelity PCR system
(Boehringer Mannheim) by using the first-strand cDNA as a template. The
amplifications were performed with Robocycler Gradient 96 (Stratagene)
in a program of 94°C for 3 min, 30 cycles of 94°C for 40 s and
60°C (for FA5 and FA3 amplification) or 52°C (for FB5 and FB3
amplification) for 40 s, 72°C for 2 min 30 s, and finally
72°C for 10 min. Four primer pairs were used for amplifications of
the corresponding fragments, of which A5 and A3AP were used for
amplification of fragment FA5, A5SP and A3 were used for fragment FA3,
B5 and B3AP were used for fragment FB5, and B5SP and B3 were used for
fragment FB3. Fragment FA5 digested with EcoRI and
SalI was cloned into the EcoRI/SalI
site of pBssK vector (Stratagene) to obtain plasmid FA5-pBssK.
Subsequently, PCR fragment FA3 was subcloned into the SalI
and KpnI sites of plasmid FA5-pBssK to generate FA-pBssK, which carried the full-length fragment A cDNA (Fig.
1). To obtain a cDNA clone of segment B
of HK46, two cDNA fragments, FB5 and FB3, were amplified by PCR with
two primer pairs, B5-B3AP and B5SP-B3, respectively, by using
first-strand cDNA of segment B as a template. There was a unique
BglII site in the overlapping region of fragments FB5 and
FB3. Because vector pBssK lacks a BglII site, another
plasmid, pBssK-Bgl, in which a BglII linker was cloned into
the EcoRI site of pBssK, was employed to construct the
full-length cDNA clone of fragment B. Fragment FB3 digested with
BglII and XbaI was cloned into the
BglII/XbaI site of plasmid pBssK-Bgl to obtain
plasmid FB3-pBssK. Subsequently, PCR fragment FB5 was subcloned into
the EcoRI and BglII sites of FB3-pBssK to yield a
plasmid containing a full-length cDNA copy of segment B (Fig. 1). DNA
sequences were determined by primer walking with a dRhodamine
Terminator Cycle Sequencing Kit (Perkin-Elmer) in an automatic
sequencer (A310 Genetic Analyzer; Perkin-Elmer).
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Adaptation of Very Virulent Infectious Bursal
Disease Virus to Chicken Embryonic Fibroblasts by Site-Directed
Mutagenesis of Residues 279 and 284 of Viral Coat Protein
VP2
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
Asn) and 284 (AlaThr)
of the VP2 protein yielded a recombinant virus which was able to be
passaged in CEFs, whereas the wild-type cDNAs and an amino acid
substitution at residue 330 (SerArg) of the VP2 protein alone did
not yield viable virus. The results indicated that mutation of other
viral proteins, including VP1, VP3, VP4, and VP5, was not required for
CEF adaptation of the virus. The same approach may be used to produce
CEF-adapted strains from newly evolved IBDVs or to manipulate the
antigenicity of the virus.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
TABLE 1.
Primers for genome cloning and mutagenesis
of IBDVa
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FIG. 1.
Construction of full-length cDNA clones. Four cDNA
fragments derived from very virulent strain HK46, designated FA5 (5'
end fragment of segment A), FA3 (3' end fragment of segment A), FB5 (5'
end fragment of segment B), and FB3 (3' end fragment of segment B),
were independently amplified by four primer pairs. Fragment FA5
digested with EcoRI and SalI was cloned into the
EcoRI/SalI site of pBssK to obtain plasmid
FA5-pBssK. Subsequently, fragment FA3 was subcloned into the
SalI and KpnI sites of plasmid FA5-pBssK to
generate FA-pBssk, which carried the full-length fragment A cDNA.
Fragment FB3 digested with BglII and XbaI was
cloned into the BglII/XbaI site of plasmid
pBssK-Bgl to obtain plasmid FB3-pBssK. Subsequently, fragment FB5 was
subcloned into the EcoRI and BglII sites of
FB3-pBssK to yield a plasmid containing a full-length cDNA copy of
segment B.
Site-directed mutagenesis by PCR.
Two combinations of
mutations were introduced into the segment A cDNA of strain HK46. (i)
In mutant NT, substitutions at nucleotide positions 966 (GA) and 981 (GA) resulted in amino acid substitutions at residues 279 (AspAsn) and 284 (AlaThr). (ii) In mutant R, a nucleotide
substitution at position 1121 (TA) resulted in amino acid
substitution at position 330 (SerArg). To construct mutant plasmid
NT-FA-pBssK, two primer pairs, designated A5-NTA and NTS-A3AP, were
used to amplify two DNA fragments, of 991 and 786 bp, respectively. These two DNA fragments were purified, combined, and reamplified by PCR
with primers A5 and A3AP. Pfu polymerase (Stratagene) was used in PCR to enhance the fidelity. After amplification, the PCR
product of 1,756 bp was then digested with EcoRI and
SalI. The resulting fragment of 1,726 bp was cloned into the
EcoRI/SalI site of FA-pBssK to replace the
EcoRI/SalI insert of plasmid FA-pBssK to obtain
plasmid NT-FA-pBssK. The mutated sequences were confirmed by cycle PCR
sequencing as described above. Plasmid NT-FA-pBssK contained
full-length cDNA of segment A of strain HK46 but had substitutions at
nucleotide positions 966 (GA) and 981 (GA). In addition, the
identities of the mutant plasmids were further confirmed by the
disappearance of a NaeI restriction site after mutagenesis,
since the wild type was NaeI restricted (Fig.
2).
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Subcloning of the cDNA of both segments of IBDV into vector pALTER-MAX. Carrying the genes for ampicillin and chloramphenicol resistance and the cytomegalovirus immediate-early enhancer/promoter, the pALTER-MAX vector is used for mutagenesis and expression of genes in eukaryotic cells (Promega). To subclone wild-type segment A cDNA and NT mutant segment A cDNA into the pALTER-MAX vector, plasmids FA-pBssK and NT-FA-pBssK were digested with EcoRI and KpnI, and restriction fragments FA and NT-FA were cloned into the EcoRI/KpnI sites of pALTER-MAX to create plasmids FA-pALTER and NT-FA-pALTER, respectively (Fig. 2). These plasmids contained a full-length cDNA copy or a mutated segment A of strain HK46. To clone fragment FB into pALTER-MAX, plasmid FB-pBssK was digested with restriction enzymes EcoRI and XbaI. Subsequently, fragment FB was inserted into the EcoRI/XbaI site of pALTER-MAX to obtain plasmid FB-pALTER. This plasmid contained the full-length cDNA of segment B of strain HK46.
Mutation of the serine-rich heptapeptide region on VP2 by the Altered Sites II mutagenesis system. Single-strand DNA of plasmid FA-pALTER was produced by the method recommended by the supplier (Promega). A primer designated 330R, phosphorylated at the 5' end, was used for producing a mutation on plasmid FA-pALTER, in which nucleotide 1127 (T) was replaced with A. After annealing of primer 330R and the ampicillin repair oligonucleotide to the single-strand template, T4 DNA polymerase and T4 DNA ligase were added to perform mutant-strand synthesis and ligation. After incubation, the synthesis mixture was transformed into Escherichia coli ES1301 mutS competent cells by electroporation. The transformed ES1301 mutS cells were cultured at 37°C and shaken at 250 rpm overnight. Plasmid DNA was then extracted and then retransformed into E. coli JM109 competent cells. To screen for the mutant plasmid designated R-FA-pALTER, 10 colonies were screened by direct sequencing with an automatic sequencer (Fig. 2).
Generation of recombinant viruses by transfection. CEFs were grown to 80% confluence in a 12-well tissue culture plate and washed once with phosphate-buffered saline (PBS). One milliliter of serum-free EME medium (SF-EMEM) (Life Technologies) was added to each well, and the cells were incubated at 37°C for 1 h in a 5% CO2 incubator. Simultaneously, 100 µl of SF-EMEM was incubated with 10 µl of Lipofectin (Life Technologies) for 30 min at room temperature. After a 30-min incubation at room temperature, 100 µl of SF-EMEM with 5 µl (0.2 µg/µl) of pALTER plasmids FA-pALTER and FB-pALTER was added to the SF-EMEM-Lipofectin mixture and incubated at room temperature for 5 min. After removing SF-EMEM from the CEF monolayer and replacing it with 0.8 ml of fresh SF-EMEM, the plasmid-containing mixture was added to CEF monolayers. After 5 h of incubation at 37°C, the medium was replaced with EMEM containing 10% fetal bovine serum and the cells were further incubated at 37°C in a 5% CO2 incubator for several days. The modified pALTER plasmids (NT-FA-pALTER or R-FA-pALTER) and/or FB-pALTER were also transfected into CEFs by the procedure described above. After 96 h, cytopathic effect was observed. The ability of the recombinant viruses to propagate in CEFs was further tested by adding 0.1 ml of virus suspension collected 96 h posttransfection into a well of a 12-well plate containing 80% confluent CEFs with 1 ml of cell culture medium. After virus propagation in CEFs, the mutant virus was harvested and the first-strand cDNA was generated as described above. The nucleotide sequence of the recombinant virus was confirmed by DNA sequencing.
Reactivity with MAbs. Five monoclonal antibodies (MAbs) (3-1, 9-6, 17-82, 39A, and 44-18) raised against virulent strain 002/73 of IBDV by Fahey et al. (4) and three MAbs (B29, R63, and R69) raised against vaccine strain D78 by Snyder et al. (11) were used in antigen capture enzyme-linked immunosorbent assays (ELISA) to examine their immunoreactivities to several CEF-nonpermissive IBDV strains isolated from Hong Kong and China (3) and to two CEF-adapted strains, including the NT mutant derived from HK46 (HK46-NT) and strain D78 (ATCC VR-2041).
One hundred microliters of rabbit anti-IBDV immunoglobulin G (IgG) diluted in coating buffer (15 mM Na2CO3, 35 mM NaHCO3, 0.05% [wt/vol] NaN3 [pH 9.6]) at a ratio of 1:500, was added to each well of a Maxisorb microtiter plate (Nunc). After incubation at 4°C overnight, the plate was washed three times with washing buffer TBS/NT (20 mM Tris-HCl, 140 mM NaCl, 0.05% NaN3, 0.05% (vol/vol) Tween 20 [pH 7.4]) and each well was blocked by 200 µl of blocking buffer (TBS/NT with 10 mg of bovine serum albumin) at room temperature for 1 h. After three washes of the plate with washing buffer, 100 µl of bursal homogenate (10% [wt/vol] in PBS) from infected SPF chickens or undiluted virus culture media was added in duplicate. The plate was then incubated at room temperature for 1 h and washed with washing buffer before 100 µl of MAbs diluted 1:10 in diluent (washing buffer with 2% [wt/vol] nonfat skim milk) were added to the wells in duplicate. After incubation for 1 h at room temperature, the plate was washed three times with washing buffer. Subsequently, 100 µl of rabbit anti-mouse IgG-horseradish peroxidase (Dako) diluted in diluent at a ratio of 1:1,000 was added. One hour later, the plate was washed three times with washing buffer. TMB peroxidase substrate (100 µl) (Kirkegaard & Perry Laboratories) was added, and the reaction was stopped 10 min later by the addition of 50 µl of TMB stop solution (Kirkegaard & Perry Laboratories). The result was read by an ELISA reader at the optical density at 450 nm (OD450).Infectivity of recombinant virus HK46-NT on CEF cells. The titer of the amplified virus stock was determined by serial dilution and expressed as 50% tissue culture infective doses (TCID50) per milliliter. CEF cells were seeded in 96-well plates at a density of 2 × 104 cells/well, and 100 TCID50 of D78 or HK46-NT were added to each well in a 0.1-ml volume. At daily intervals (up to 6 days), 20 µl of MTS/PES [3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium/phenazine ethosulfate] solution (CellTiter 96AQ Cell proliferation assay; Promega) was added to each well and the plates were incubated at 37°C for 2 h in a humidified chamber with 5% CO2. The OD490 was then measured by an ELISA reader (SLT Spectra). Wells with 200 µl of culture medium only, without the addition of CEF cells, were measured as background signal.
Growth curve of IBDV. The growth characteristics of strains HK46-NT and D78 were compared with each other. CEF cells were seeded in 96-well plates at a density of 2 × 104 cells/well, and 100 TCID50 of D78 or HK46-NT were added to each well in triplicate. At 24-h intervals, the culture supernatant in each well was collected and the virus titers were determined and expressed as TCID50 per milliliter.
Nucleotide sequence accession numbers. The full-length sequence of the genome of IBDV strain HK46 has been deposited in GenBank under accession no. AF092943 (segment A) and AF092944 (segment B).
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Full-length cDNA sequence of the IBDV genome.
The full-length
sequences of the segment A and B genomes of the very virulent IBDV
strain HK46 are shown in Fig. 3 and
4, respectively. The segment A genome
contains 3,269 bp and encodes two polypeptides in two reading frames.
Nucleotides 86 to 532 encode a 149-residue protein, VP5, whereas
nucleotides 132 to 3167 encode a VP2-4-3 polypeptide of 1,012 residues.
The segment B genome contains 2,834 bp and encodes the RNA polymerase
(VP1) of 879 residues. The nucleotide sequence of VP2 has eight
mutations, at nucleotides 608 (TC), 809 (AG), 951 (TC), 1016 (TC), 1154 (TA), 1163 (TC), 1217 (AG), and 1274 (TA),
compared to the sequence of the VP2 hypervariable region reported
previously (3). These mutations did not result in any amino
acid substitutions, indicating a mixed virus population in the infected
bursa.
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6 to
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Generation of recombinant viruses by transfection. The pALTER plasmid containing the wild-type genome fragment A cDNAs, or the pALTER plasmids containing the mutated fragment A cDNAs, were cotransfected with the pALTER plasmid carrying the wild-type genome of fragment B. Cytopathic effects could be seen only in wells transfected with the NT mutant plasmid after a 4-day culture, not in the wells transfected with wild-type or 330R mutant plasmids even after a 7-day culture. The culture supernatants collected at day 7 from these wells were blind passaged in secondary CEFs; however, no virus was propagated. The experiment was repeated three times to confirm the result. The titer of the NT mutant virus was 104.3 TCID50/ml at day 7 posttransfection and reached 106 TCID50/ml at 3 days after the first passage. Viral RNA was recovered from the recombinant virus, and the full-length sequences of both genome segments were amplified and sequenced. The sequencing result indicated that a recombinant virus mutant with 222A, 256I, and 294I, the signature amino acid residues of very virulent IBDV strains, and 279N and 284T, the signature amino acid residues of attenuated strains was produced (Fig. 5). This recombinant virus has the conserved serine-rich heptapeptide S-W-S-A-S-G-S (sequencing data not shown).
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Reactivity of MAbs.
MAbs B29, R63, 9-6, 17-82, and 39A showed
activities toward all strains examined, whereas MAb B69 recognized
strain D78 but not any other local strain (Table
3). MAb 44-18 showed strong binding to
the very virulent IBDV strains HK46, G9201, G9303, and F9502, as well
as CEF-adapted strains D78 and the HK46-NT mutant, but had only weak
activity toward classical strains CJ801 and G9212 (Table 3). MAb 3-1 recognized all very virulent strains and classical strains but not
CEF-adapted vaccine strain D78 and the HK46-NT mutant (Table 3). Since
these two CEF-adapted strains had common amino acid residues, 279N and
284T, which were not present in non-CEF-adapted strains, these amino
acid residues may affect the binding of MAb 3-1. To further
differentiate the HK46-NT strain from the other CEF-adapted strains
derived from other parent strains, MAb B69 can be used. Many
CEF-adapted vaccine strains, including D78 (Intervet), IBD Blend
(Sanofi Inc.), Bio-Burs (Kee-Vet), Bio-Burs I (Kee-Vet), Bursa-vac
(Sterwin), Bursine (Solvary Inc.), Bur-706 (Rhone Merieux), Univax
(American Sci. Lab.), and VI-Bur-G (Vineland), are B69 positive,
whereas the HK46-NT strain, like its parent strain, is B69 negative
(14).
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Infectivity of the recombinant virus HK46-NT on CEF cells. Cytopathogenicity of the recombinant virus HK46-NT was compared with that of D78 in CEF cells by using the MTS assay. Two individual experiments were carried out, and the results were reproducible. Figure 6 shows the relative numbers of viable CEF cells at different days postinfection after they were incubated with 100 TCID50 of virus. The signal at OD490 was directly proportional to the number of metabolically active cells. Without addition of virus, the number of viable cells in the control wells increased in the first few days and rapidly dropped to a very low level at day 5, indicating that the cells were overgrown and had died. In both experiments, the cells were lysed more rapidly by strain HK46-NT than by strain D78, implying that HK46-NT was more cytopathogenic than D78 to CEF cells.
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Growth curve of IBDV. To compare the replication kinetics of strains HK46-NT and D78, CEF cells were infected with each virus and the virus titers were determined and expressed as TCID50 per milliliter. Figure 7 shows the growth curve of each virus at different days postinfection. The results indicate that the mutant virus replicated at a higher speed and generated virus to a higher titer than did strain D78.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Heine et al. (5) aligned the VP2 amino acid sequences of virulent strains (52/70, STC, and variant E) with CEF-adapted strains of low pathogenicity (002-73, CU-1, and PBG98) and identified the heptapeptide S-W-S-A-S-G-S (residues 326 to 332) as the only conserved sequence in strains of high pathogenicity. It was hypothesized that the serine-rich motif could form hydrogen bonds which might be involved in intra- or intermolecular interactions important for virulence (5). It was also suggested that the substitution of one or more serine residues in the CEF-adapted, nonpathogenic strains might prevent such interaction and affect the virulence. In contrast, Yamaguchi et al. (17) have aligned the segment A sequence of a highly virulent strain, OKYM, and its CEF-adapted, attenuated strain, OKYMT, and discovered that both of them had the conserved heptapeptide S-W-S-A-S-G-S. There were five amino acid differences between the two Japanese strains, of which substitutions at positions 279 (Asp to Asn) and 284 (Ala to Thr) were commonly found in CEF-adapted strains.
Our results indicated that the substitution of amino acid residues at positions 279 (Asp to Asn) and 284 (Ala to Thr) of the VP2 coat protein were adequate to convert a CEF-nonpermissive, very virulent strain, HK46, to a CEF-adapted strain. In contrast, a substitution at position 330 (Ser to Arg) could not convert a CEF-nonpermissive strain to a permissive strain. Additionally, since the CEF-adapted strain HK46-NT shared identical VP1, VP3, VP4, and VP5 sequences with the wild-type CEF-nonpermissive parent strain, mutation of these viral proteins was not required for CEF adaptation. The acquisition of 279N and 284T may enable the virus to acquire a novel receptor binding site on CEF cells (10).
The principal method of controlling IBD in young chickens is by vaccination with a live attenuated strain of IBDV at the age of 0 to 5 weeks or by transferring high levels of maternal antibody induced by the administration of live and killed IBD vaccines to breeder hens (15, 16). The live attenuated vaccines on the market are generally derived by serial passage of classical or variant strains in embryonating SPF eggs or in primary cell culture, such as CEFs. Only strains with their virulence reduced or eliminated by these methods can be used as live attenuated vaccines. Inactivated vaccines are prepared by propagating the virus in cell culture or in SPF chickens, and the vaccines are subsequently inactivated by heat or chemical treatment. The attenuated strains derived from the classical and variant strains can usually protect birds from infection by their parent strains. However, many of these vaccine strains do not offer 100% protection against the very virulent strains discovered in recent years (12). Since very virulent strains could break through higher levels of maternal antibodies than are induced by the current vaccine strains (12), it is important to develop attenuated vaccine strains from very virulent strains.
Presently, live infectious bursal disease vaccines are derived from multiple passages of the virus in CEFs or in embryonating eggs. Hence, the method of producing live attenuated virus is a random, uncontrolled process; as a result, these vaccines suffer from a number of drawbacks. First, a field virus may not be adapted to CEFs after many attempts, and hence no live attenuated virus may be derived. Second, even if some of the field viruses can be adapted in CEFs, a population of viruses of different characteristics and different degrees of virulence are generated. Because uncontrolled mutations are introduced into the viral genome during serial passages, a population of virus particles heterogeneous in their virulence and immunizing properties is generated. Prior to vaccine development, a single virus has to be cloned and the pathogenicity of each cloned virus has to be tested, which is a lengthy and labor-intensive process.
Techniques for controlled manipulation of the IBDV genome developed in
this project may allow the generation of CEF-adapted viruses and avoid
the disadvantages of the conventional virus passage approach. The
process is straightforward, controllable, and can be applied to any
newly evolved strain. The genome of the generated virus is known and no
virus cloning is required. To determine the potential for applying the
NT mutant virus as a live vaccine against very virulent IBDV, the
pathogenicity of the mutant virus must be tested in vivo on SPF
chickens. Recently, Yao et al. (19) produced a recombinant
virus (rD78NS
IBDV) lacking VP5 expression by using infectious cRNA,
which was derived from the CEF-adapted strain D78. The VP5-deficient
mutant had a lower cytotoxic effect on CEF cells and grew to lower
titers than the parent strain. The virus also failed to induce any
pathological lesions or clinical signs of disease in SPF chickens. It
will be interesting to produce a VP5-deficient mutant from HK46-NT to
test which of the mutants is a better candidate for vaccination against
very virulent IBDV strains.
In summary, this is the first report of a method for producing a recombinant CEF-adapted IBDV strain from a CEF-nonpermissive strain by direct transfection of engineered vector DNA into CEFs. The methods reported recently (8, 9, 19) involve more tedious procedures, since generation of cRNA from a T7 promoter and subsequent transfection of the cRNA into CEFs were required. More importantly, the cRNAs produced by these groups were derived from D78, a CEF-permissive strain by nature. The vectors FA-pALTER and FB-pALTER could be employed as templates for developing CEF-adapted strains from any newly evolved IBDV strain, including very virulent, variant, or classical strains, by first subcloning a partial VP2 cDNA generated from these strains by reverse transcription-PCR into the NdeI (nucleotides 646 to 651) and SpeI (nucleotides 1181 to 1186) sites on VP2 cDNA in FA-pALTER and subsequently introducing 279N and 284T into the VP2 cDNA by mutagenesis. Hence, the antigenicity and pathogenicity of the virus can be manipulated.
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ACKNOWLEDGMENTS |
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We are very grateful to Jagoda Ignjatovic of CSIRO, Division of Animal Health, Australia, for supplying monoclonal antibodies. We also thank K. F. Shortridge, of the University of Hong Kong, and T. van den Berg for revision of the manuscript.
This work was supported by an Industrial Support Fund (AF/247/95) from the Department of Industry and a grant from the Research Grants Council (project HKU 7222/98M) of the Hong Kong Special Administrative Region Government, China.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Zoology, The University of Hong Kong, Pokfulam, Hong Kong, China. Phone: 852-28598915. Fax: 852-28574672. E-mail: bllim{at}hkucc.hku.hk.
Present address: Department of Animal Science, South China
Agricultural University, Wushan, Tianhe, Guangzhou, Guangdong Province, China.
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REFERENCES |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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| 1. |
Becht, H.,
H. Muller, and H. K. Muller.
1988.
Comparative studies on structural and antigenic properties of two serotypes of infectious bursal disease virus.
J. Gen. Virol.
69:631-640 |
| 2. | Brown, M. D., and M. A. Skinner. 1996. Coding sequences of both genome segments of a European `very virulent' infectious bursal disease virus. Virus Res. 40:1-15[Medline]. |
| 3. | Cao, Y. C., W. S. Yeung, M. Law, Y. Z. Bi, F. C. Leung, and B. L. Lim. 1998. Molecular characterization of seven Chinese isolates of infectious bursal disease virus: classical, very virulent and variant strains. Avian Dis. 42:340-351[Medline]. |
| 4. | Fahey, K. J., P. McWaters, M. A. Brown, K. Erny, V. J. Murphy, and D. R. Hewish. 1991. Virus-neutralizing and passively protective monoclonal antibodies to infectious bursal disease virus of chickens. Avian Dis. 35:365-373[Medline]. |
| 5. |
Heine, H. G.,
M. Haritou,
P. Failla,
K. Fahey, and A. Azad.
1991.
Sequence analysis and expression of the host-protective immunogen VP2 of a variant strain of infectious bursal disease virus which can circumvent vaccination with standard type I strains.
J. Gen. Virol.
72:1835-1843 |
| 6. | Kibenge, F. S., and V. Dhama. 1997. Evidence that virion-associated VP1 of avibirnaviruses contains viral RNA sequences. Arch. Virol. 142:1227-1236[Medline]. |
| 7. |
Mundt, E.,
J. Beyer, and H. Muller.
1995.
Identification of a novel viral protein in infectious bursal disease virus-infected cells.
J. Gen. Virol.
76:437-443 |
| 8. | Mundt, E., B. Kollner, and D. Kretzschmar. 1997. VP5 of infectious bursal disease virus is not essential for viral replication in cell culture. J. Virol. 71:5647-5651[Abstract]. |
| 9. |
Mundt, E., and V. N. Vakharia.
1996.
Synthetic transcripts of double-stranded Birnavirus genome are infectious.
Proc. Natl. Acad. Sci. USA
93:11131-11136 |
| 10. |
Nieper, H., and H. Muller.
1996.
Susceptibility of chicken lymphoid cells to infectious bursal disease virus does not correlate with the presence of specific binding sites.
J. Gen. Virol.
77:1229-1237 |
| 11. | Snyder, D. B., D. P. Lana, B. R. Cho, and W. W. Marquardt. 1988. Group and strain-specific neutralization sites of infectious bursal disease virus defined with monoclonal antibodies. Avian Dis. 32:527-534[Medline]. |
| 12. | Tsukamoto, K., N. Tanimura, S. Kakita, K. Ota, M. Mase, K. Imai, and H. Hihara. 1995. Efficacy of three live vaccines against highly virulent infectious bursal disease virus in chickens with or without maternal antibodies. Avian Dis. 39:218-229[Medline]. |
| 13. | Vakharia, V. N., J. He, B. Ahamed, and D. B. Snyder. 1994. Molecular basis of antigenic variation in infectious bursal disease virus. Virus Res. 31:265-273[Medline]. |
| 14. | Vakharia, V. N., and D. Snyder. 21 January 1997. Specific DNA and RNA sequences associated with US IBDV variants, vector carrying DNA sequences, host carrying cloned vector, deduced amino acid sequences, vaccine and method of vaccination. U.S. patent 5,595,912. |
| 15. | Wyeth, P. J., and N. Chettle. 1982. Comparison of the efficacy of four inactivated infectious bursal disease oil emulsion vaccines. Vet. Rec. 110:359-361[Abstract]. |
| 16. | Wyeth, P. J., and N. J. Chettle. 1990. Use of infectious bursal disease vaccines in chicks with maternally derived antibodies. Vet. Rec. 126:577-578[Abstract]. |
| 17. | Yamaguchi, T., M. Ogawa, Y. Inoshima, M. Miyoshi, H. Fukushi, and K. Hirai. 1996. Identification of sequence changes responsible for the attenuation of highly virulent infectious bursal disease virus. Virology 223:219-223[Medline]. |
| 18. | Yamaguchi, T., M. Ogawa, M. Miyoshi, Y. Inoshima, H. Fukushi, and K. Hirai. 1997. Sequence and phylogenetic analyses of highly virulent infectious bursal disease virus. Arch. Virol. 142:1441-1458[Medline]. |
| 19. |
Yao, K.,
M. A. Goodwin, and V. N. Vakharia.
1998.
Generation of a mutant infectious bursal disease virus that does not cause bursal lesions.
J. Virol.
72:2647-2654 |
Journal of Virology, April 1999, p. 2854-2862, Vol. 73, No. 4
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Copyright © 1999, American Society for Microbiology. All rights reserved.
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